JP2015149556A - Radio communication system, radio communication device and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To select a transmission scheme for improving a transmission rate when transmitting a data signal to a terminal station device by using any of a plurality of transmission schemes.SOLUTION: A radio communication system comprises a base station device which comprises: a transmission rate calculation part for calculating when transmitting a data signal to a terminal station device by using any one of a plurality of transmission schemes, a transmission rate with respect to each transmission scheme based on an overhead including transmission and reception of a control signal, a data length of the data signal, a modulation scheme, a code rate and the number of sub-carriers used for transmission; a transmission signal generation part for modulating the data signal to be transmitted to the terminal station device to a radio packet signal corresponding to each of the plurality of transmission schemes; a transmission scheme selection part for causing the transmission signal generation part to generate the radio packet signal depending on the transmission scheme corresponding to the maximum transmission rate among the plurality of transmission rates calculated by the transmission rate calculation part; and a transmission part converting the radio packet signal generated depending on the selection by the transmission scheme selection part and transmitting the converted radio signal.

Description

  The present invention relates to a wireless communication system, a wireless communication apparatus, and a wireless communication method.

  There is an IEEE802.11a standard as a high-speed wireless access system using a 5 GHz (gigahertz) band. This system uses an Orthogonal Frequency Division Multiplexing (OFDM) modulation method, which is a technique for stabilizing the characteristics in a multipath fading environment, and achieves a maximum throughput of 54 Mbps (megabits per second). (For example, Non-Patent Document 1).

  Further, in IEEE 802.11n, a MIMO (Multiple Input Multiple Output) technique capable of realizing spatial multiplexing using a plurality of antennas using the same time and the same frequency channel, and the 20 MHz that has been used individually until now. It is possible to realize a high-speed communication by channel bonding technology using a frequency channel of 40 MHz by using two (megahertz) frequency channels simultaneously (for example, non-patent literature). 1).

  Furthermore, in IEEE802.11ac, the standard is being formulated, channel bonding technology that simultaneously uses four 20 MHz frequency channels and uses it as an 80 MHz frequency channel, and multi-user MIMO technology at the same frequency channel and at the same time. Spatial division multiple access (SDMA) transmission technology that simultaneously transmits to a plurality of wireless stations will be adopted, aiming to realize wireless communication that is faster and more efficient than IEEE 802.11n. (For example, Non-Patent Document 2).

  Further, in the next generation wireless LAN standardization, orthogonal frequency division multiple access (OFDMA) that assigns and transmits data of a plurality of wireless stations that can be further improved in efficiency by realizing flexible allocation of frequency bands to different subcarriers. Orthogonal Frequency Division Multiple Access) transmission technology has been studied (for example, Non-Patent Document 3).

  Here, SDMA transmission and OFDMA transmission assuming a wireless LAN system will be specifically described with reference to the drawings. FIG. 16 is a diagram illustrating an example of a wireless LAN system model. The wireless LAN system shown in FIG. 16 includes a base station device 91, a terminal station device 92-1 and a terminal station device 92-2 that perform wireless packet communication with the base station device 91. The base station apparatus 91 illustrated in FIG. 16 can perform transmission to a plurality of terminal station apparatuses 92-1 and 92-2 at the same time using SDMA transmission or OFDMA transmission.

  FIG. 17 is a time chart showing an operation example of SDMA transmission adopted in IEEE802.11ac. In the operation example shown in FIG. 17, carrier sense (CS: Carrier Sense) for confirming whether other radio stations are communicating, and null data packet announcement (NDPA: Null Data Packet Announcement for notifying transmission of a null data packet). ), A null data packet (NDP) composed of null data, a beamforming report (BR: Beamforming Report) for notifying propagation channel information estimated from NDP, and beamforming for requesting propagation channel information Report poll (BRP: Beamforming Report Poll), data (Data1 and Data2) for the terminal station apparatus 92-1 and the terminal station apparatus 92-2, and a block ACK (BA: Block Acknowledgment) for notifying whether the signal is correctly received Block ACK request for requesting block ACK SDMA transmission is performed using each frame of the bets BAR (Block Acknowledgment Request).

  Assume that the base station device 91 generates packet data (transmission target data) to be transmitted to the terminal station device 92-1 and the terminal station device 92-2. In response to this, the base station apparatus 91 executes CS at random time intervals. The CS determines whether the idle state in which the communication frequency band is not used or the busy state in which the communication frequency band is used.

  Based on the CS executed at time t1 in FIG. 17, the base station apparatus 91 detects that the communication frequency band is in an idle state. In response to this, the base station apparatus 91 generates and transmits NDPA in the period from time t3 to time t4.

  In the period from time t5 to time t6, the base station apparatus 91 generates and transmits an NDP for propagation channel estimation. Further, the base station device 91 detects that the destination of the transmission target data is the terminal station device 92-1 and the terminal station device 92-2, and sends the destination to the terminal station device 92-1 and the terminal station device 92-2. Transmit the measurement signal specified as. In response to reception of the measurement signal transmitted from the base station apparatus 91, the terminal station apparatus 92-1 and the terminal station apparatus 92-2 measure the propagation channel characteristics within the period from time t5 to time t6. The terminal station apparatus 92-1 and the terminal station apparatus 92-2 generate BR including propagation channel information obtained by quantizing the measured propagation channel characteristics.

  In the period from time t7 to time t8, the terminal station apparatus 92-1 transmits the generated BR. In the period from time t9 to time t10, the base station apparatus 91 generates and transmits a BRP requesting BR to the terminal station apparatus 92-2. In the period from time t11 to time t12, the terminal station apparatus 92-2 transmits the generated BR in accordance with the BRP from the base station apparatus 91. The base station device 91 calculates a transmission weight using the BR notified from the terminal station device 92-1 and the terminal station device 92-2, and generates a transmission signal including transmission target data (Data1 and Data2). .

  In a period from time t13 to time t14, the base station device 91 transmits a transmission signal using the calculated transmission weight, thereby directing transmission target data to the terminal station device 92-1 and the terminal station device 92-2. Send. Data transmitted in this period is converted into a frame suitable for wireless communication, for example. In addition, when frame aggregation is applied, data transmitted in a period from time t13 to time t14 is a data unit in which a predetermined number of frames are connected.

  In a period from time t15 to time t16, the terminal station apparatus 92-1 transmits BA corresponding to the end of reception of data transmitted by the base station apparatus 91 at time t14. The base station device 91 receives the BA from the terminal station device 92-1, and executes a predetermined process according to the reception of the BA. Specifically, the base station apparatus 91 determines that the data is normally received on the receiving side, for example, by receiving the BA, and transitions to the next data transmission / reception process. When the time-out occurs without receiving the BA, the base station apparatus 91 executes processing such as retransmitting the transmission target data.

In the period from time t17 to time t18, the base station device 91 generates a BAR requesting the terminal station device 92-2 to transmit BA, and transmits the generated BAR. In the period from time t19 to time t20, the terminal station apparatus 92-2 transmits BA according to the BAR transmitted by the base station apparatus 91. The base station device 91 receives the BA from the terminal station device 92-2 and executes a predetermined process according to the reception of the BA.
According to the time chart as described above, the wireless LAN system performs SDMA transmission.

  FIG. 18 is a time chart showing an operation example of OFDMA transmission. In FIG. 18, CS for confirming whether other radio stations are communicating, data to be transmitted to the terminal station device 92-1 and the terminal station device 92-2 (Data1 and Data2), and whether the data has been correctly received. OFDMA transmission is performed using each frame of the BA for notifying whether or not and the BAR for requesting the BA.

  Assume that the base station device 91 generates packet data (transmission target data) to be transmitted to the terminal station device 92-1 and the terminal station device 92-2. In response to this, the base station apparatus 91 executes CS at random time intervals. The CS determines whether the idle state where the communication frequency band is not used or the busy state where the communication frequency band is used.

  Based on the CS executed at time t1 in FIG. 18, the base station device 91 detects that the communication frequency band is in an idle state. In response to this, in the period from time t3 to time t4, the base station apparatus 91 transmits the transmission target data. Note that data transmitted in the period from time t3 to time t4 is converted into a frame suitable for wireless communication, for example. In addition, when frame aggregation is applied, data transmitted in a period from time t3 to time t4 is a data unit in which a predetermined number of frames are connected.

  In the period from time t5 to time t6, the terminal station apparatus 92-1 transmits BA in response to the base station apparatus 91 completing reception of transmission data at time t4. The base station apparatus 91 receives the BA transmitted by the terminal station apparatus 92-1, and executes a predetermined process according to the reception of the BA.

In a period from time t7 to time t8, the base station device 91 generates a BAR requesting a BA from the terminal station device 92-2, and transmits the generated BAR. The base station device 91 receives the BA transmitted by the terminal station device 92-2 and executes a predetermined process according to the reception of the BA.
According to the time chart as described above, the wireless LAN system performs OFDMA transmission.

Masahiro Morikura, Shuji Kubota (supervised), “Revised Third Edition 802.11 High-Speed Wireless LAN Textbook”, Impress R & D Inc., April 11, 2008 Quentin H. Spencer, A. Lee Swindlehurst, and Martin Haardt, "Zero-Forcing Methods for Downlink Spatial Multiplexing in Multiuser MIMO Channels", IEEE Transactions on Signal Processing, Vol.52, No.2, February 2004, p.461- 471 Takeshi Hattori (edited), "OFDM / OFDMA textbook", Impress R & D, Inc., September 21, 2008

  By the way, in a future wireless communication system, by using the above-described SDMA transmission and OFDMA transmission, transmission to a plurality of terminal station devices at the same time is achieved, thereby achieving high speed and high efficiency of wireless communication. It is being considered. In other words, a base station apparatus in a future wireless communication system has SDMA transmission and OFDMA transmission in addition to time division multiple access (TDMA) transmission in which communication is performed by dividing time. Therefore, the base station apparatus is required to switch the radio transmission scheme used for transmission depending on the communication environment of the terminal station apparatus.

  In a general wireless transmission switching method, the transmission capacity in the physical layer is calculated and compared, and the wireless transmission method with the highest transmission capacity is selected. By using this method, the maximum capacity is obtained in the physical layer. However, in actual wireless communication, since there is an overhead such as a control signal, the actual transmission efficiency differs depending on the wireless transmission method. In OFDMA transmission, there is overhead such as BA as shown in FIG. Since this overhead increases depending on the number of terminal station apparatuses that transmit, the transmission efficiency varies depending on the number of terminal station apparatuses.

  Further, in SDMA transmission, in addition to overhead such as BA, there is overhead for acquiring propagation channel information necessary for using the multiuser MIMO technology. Therefore, in SDMA transmission and OFDMA transmission, the amount of overhead varies greatly depending on the number of terminal station devices to be transmitted, etc., so switching the wireless transmission scheme based on the transmission capacity of the physical layer maximizes the actual transmission rate. There is a problem that you can not.

  In view of the above circumstances, the present invention provides a radio communication system capable of selecting a transmission method for improving a transmission rate when transmitting a data signal to a terminal station apparatus using any one of a plurality of transmission methods, An object of the present invention is to provide a wireless communication apparatus and a wireless communication method.

  One aspect of the present invention is a wireless communication system including a base station apparatus and a plurality of terminal station apparatuses, wherein the base station apparatus transmits a data signal to the terminal using any one of a plurality of transmission schemes. When transmitting to a station device, the transmission rate is determined for each transmission method based on the overhead including transmission and reception of control signals, the data length of the data signal, the modulation method, the coding rate, and the number of subcarriers used for transmission. A transmission rate calculation unit to calculate, a transmission signal generation unit that modulates a data signal to be transmitted to the terminal station apparatus into radio packet signals corresponding to each of the plurality of transmission methods, and a plurality of transmissions calculated by the transmission rate calculation unit A transmission method selection unit that selects the transmission signal generation unit to generate a radio packet signal according to a transmission method corresponding to the maximum transmission rate among the transmission rates; and the transmission method selection unit It is a wireless communication system, comprising a transmitter which transmits the radio packet signal generated in response to a selection by converting to a radio signal.

  In addition, according to an aspect of the present invention, in the above wireless communication system, the transmission rate calculation unit includes transmission / reception of a control signal in a case where a data signal is transmitted to the terminal station apparatus using time division multiple access transmission. A time division multiple access transmission rate calculation unit for calculating the first transmission rate based on the overhead, the data length of the data signal, the modulation scheme, the coding rate, and the number of subcarriers used for transmission, and orthogonal frequency division Overhead including transmission / reception of control signals, data length of data signals, modulation scheme, coding rate, and number of subcarriers used for transmission when transmitting data signals to the terminal station apparatus using multiple access transmission And an orthogonal frequency division multiple access transmission rate calculation unit that calculates a second transmission rate based on the transmission signal, wherein the transmission signal generation unit transmits to the terminal station device A time division multiple access transmission signal generator for modulating a data signal into a radio packet signal corresponding to time division multiple access transmission, and a data signal transmitted to the terminal station apparatus to a radio packet signal corresponding to orthogonal frequency division multiple access transmission An orthogonal frequency division multiple access transmission signal generation unit that modulates, the transmission method selection unit compares the first transmission rate and the second transmission rate, and the time division multiple access transmission signal generation unit The orthogonal frequency division multiple access transmission signal generation unit is selected to generate a radio packet signal.

  In addition, according to an aspect of the present invention, in the above wireless communication system, the transmission rate calculation unit includes transmission / reception of a control signal in a case where a data signal is transmitted to the terminal station apparatus using time division multiple access transmission. A time division multiple access transmission rate calculation unit for calculating a first transmission rate based on an overhead, a data length of a data signal, a modulation scheme, a coding rate, and the number of subcarriers used for transmission, and a space division multiple When transmitting a data signal to the terminal station apparatus using connection transmission, overhead including transmission / reception of a control signal, data length of the data signal, modulation scheme, coding rate, and number of subcarriers used for transmission A space division multiple access transmission rate calculation unit that calculates a second transmission rate based on the data signal, wherein the transmission signal generation unit transmits the data signal to the terminal station device A time division multiple access transmission signal generator that modulates a radio packet signal corresponding to time division multiple access transmission, and a space division that modulates a data signal transmitted to the terminal station apparatus to a radio packet signal corresponding to space division multiple access transmission A multiple access transmission signal generation unit, wherein the transmission method selection unit compares the first transmission rate and the second transmission rate to compare the time division multiple access transmission signal generation unit and the spatial division multiple. The connection transmission signal generation unit is selected to generate a radio packet signal.

  In addition, according to an aspect of the present invention, in the above wireless communication system, the transmission rate calculation unit transmits and receives a control signal when transmitting a data signal to the terminal station apparatus using orthogonal frequency division multiple access transmission. And an orthogonal frequency division multiple access transmission rate calculation unit that calculates a third transmission rate based on the overhead including the data length, the data length of the data signal, the modulation scheme, the coding rate, and the number of subcarriers used for transmission. The transmission signal generation unit further includes an orthogonal frequency division multiple access transmission signal generation unit that modulates a data signal to be transmitted to the terminal station apparatus into a radio packet signal corresponding to orthogonal frequency division multiple access transmission, and the transmission method selection And comparing the first transmission rate, the second transmission rate, and the third transmission rate with the time division multiple access transmission signal generation unit and the spatial component. And selects one of whether to generate a wireless packet signal with multiple access transmission signal generating section and the orthogonal frequency division multiple access transmission signal generating section.

  Further, according to one aspect of the present invention, in the above wireless communication system, the terminal station device acquires a propagation channel information between the device itself and the base station device for each subcarrier; A terminal station transmitter that transmits the propagation channel information to the base station apparatus, wherein the base station apparatus uses the propagation channel information received from the terminal station apparatus to calculate a correlation value between subcarriers. Further comprising a propagation channel correlation calculation unit for calculating for each device, wherein the space division multiple access transmission rate calculation unit transmits and receives control signals when transmitting a data signal to the terminal station device using space division multiple access transmission Including the data length of the data signal, the modulation length, the coding rate, the number of subcarriers used for transmission, and the correlation value. And calculates the transmission rate of.

  In addition, according to one embodiment of the present invention, overhead including transmission / reception of a control signal and data length of a data signal when a data signal is transmitted to a plurality of terminal station apparatuses using any one of a plurality of transmission schemes are provided. A transmission rate calculation unit that calculates a transmission rate for each transmission method based on a modulation method, a coding rate, and the number of subcarriers used for transmission, and a plurality of transmissions of data signals to be transmitted to the terminal station device A transmission signal generation unit that modulates a wireless packet signal according to each method, and a wireless transmission to the transmission signal generation unit according to a transmission method corresponding to the maximum transmission rate among a plurality of transmission rates calculated by the transmission rate calculation unit A transmission method selection unit that selects generation of a packet signal, and a transmission that converts the wireless packet signal generated according to the selection by the transmission method selection unit into a wireless signal and transmits the signal. It is a wireless communication device, characterized in that it comprises a part.

  Another embodiment of the present invention is a wireless communication method in a wireless communication system including a base station apparatus and a plurality of terminal station apparatuses, and the data signal is transmitted to the terminal using any one of a plurality of transmission methods. When transmitting to a station device, the transmission rate is determined for each transmission method based on the overhead including transmission and reception of control signals, the data length of the data signal, the modulation method, the coding rate, and the number of subcarriers used for transmission. A transmission rate calculating step to calculate, a transmission method selecting step for selecting a transmission method corresponding to the maximum transmission rate among a plurality of transmission rates calculated in the transmission rate calculating step, and the transmission selected in the transmission method selecting step A transmission signal generation step of modulating a data signal into a wireless packet signal according to a method, and converting the wireless packet signal into a wireless signal; Is a wireless communication method characterized by comprising a transmission step of signal to.

  According to the present invention, based on the control signal overhead, data length, modulation scheme, coding rate, and transmission band information, it is possible to select a transmission scheme that maximizes the transmission rate among a plurality of transmission schemes. Therefore, it is possible to select a transmission method that improves the transmission speed.

It is a figure which shows an example of the radio | wireless communications system in 1st Embodiment which concerns on this invention. It is a block diagram which shows the structural example of the base station apparatus 100 in the embodiment. It is a figure which shows the overhead length of TDMA transmission in the radio | wireless communications system of the embodiment. It is a figure which shows the overhead length of the OFDMA transmission in the radio | wireless communications system of the embodiment. It is a block diagram which shows the structure of the terminal station apparatus 200 in the embodiment. It is a flowchart which shows the transmission system selection process which the base station apparatus 100 in the embodiment performs. It is a block diagram which shows the structural example of the base station apparatus 300 in 2nd Embodiment. It is a figure which shows the overhead length of SDMA transmission in the radio | wireless communications system of the embodiment. It is a block diagram which shows the structural example of the terminal station apparatus 400 in the embodiment. It is a flowchart which shows the transmission system selection process which the base station apparatus 300 in the embodiment performs. It is a block diagram which shows the structural example of the base station apparatus 500 in 3rd Embodiment. It is a block diagram which shows the structural example of the terminal station apparatus 600 in the embodiment. It is a flowchart which shows the transmission system selection process which the base station apparatus 500 in the embodiment performs. It is a block diagram which shows the structural example of the base station apparatus 700 in 4th Embodiment. It is a block diagram which shows the structural example of the base station apparatus 800 in 5th Embodiment. It is a figure which shows an example of a wireless LAN system model. It is a time chart which shows the operation example of the SDMA transmission employ | adopted by IEEE802.11ac. It is a time chart which shows the operation example of OFDMA transmission.

  Hereinafter, a wireless communication system, a wireless communication apparatus, and a wireless communication method according to embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is a diagram illustrating an example of a wireless communication system according to the first embodiment of the present invention. As shown in the figure, the wireless communication system includes a base station device 100 and two terminal station devices 200 (200-1 and 200-2) that perform wireless packet communication with the base station device 100. Base station apparatus 100, terminal station apparatus 200-1, and terminal station apparatus 200-2 use the same frequency channel using a CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance) scheme. Wireless packet communication.

In wireless packet communication, transmitted and received wireless packets include an identifier indicating a transmission station and a destination station. Here, the transmitting station is a device that generates and transmits a wireless packet, and the destination station is a device that is the destination of the wireless packet. The base station device 100 is, for example, an access point in a wireless LAN, and the terminal station device 200-1 and the terminal station device 200-2 are computers, portable information electronic devices, and the like. In the present embodiment, an example in which the wireless communication system includes two terminal station apparatuses 200 is shown, but three or more terminal station apparatuses 200 may be included. Here, the propagation channel information of the subcarrier number k between the base station apparatus 100 and the terminal station apparatus 200-1 is represented by H1 _{, k} , and the propagation between the base station apparatus 100 and the terminal station apparatus 200-2. Channel information is represented by H2 _{, k} .

  FIG. 2 is a block diagram illustrating a configuration example of the base station apparatus 100 according to the first embodiment. As illustrated in FIG. 2, the base station apparatus 100 includes antennas 101-1 to 101-N, reception units 102-1 to 102-N, a demodulation unit 103, a network interface 104, an overhead calculation unit 105, a storage unit 106, and a TDMA. A transmission rate calculation unit 107, an OFDMA transmission rate calculation unit 108, a transmission method selection unit 109, a TDMA transmission signal generation unit 110, an OFDMA transmission signal generation unit 111, and transmission units 112-1 to 112-N are provided.

  Each of the receiving units 102-1 to 102-N is connected to one of the antennas 101-1 to 101-N on a one-to-one basis. Receiving sections 102-1 to 102-N are signals obtained by performing frequency conversion (down conversion) of received signals received via connected antennas 101-1 to 101-N, adjustment of received power, and the like. Is output to the demodulator 103.

  The demodulator 103 demodulates the signals input from the receivers 102-1 to 102-N and outputs the acquired data signal to the network interface 104.

  The network interface 104 converts the data signal input from the demodulation unit 103 into a packet used in the external network and transmits the packet to the external network. The network interface 104 converts a packet received from an external network into a data signal. The network interface 104 outputs the data signal converted from the packet to the TDMA transmission signal generation unit 110, the OFDMA transmission signal generation unit 111, and the overhead calculation unit 105.

  The overhead calculation unit 105 inputs a data signal from the network interface 104. Based on the data of the terminal station apparatus 200 included in the data signal, the overhead calculation unit 105 transmits time required for transmission / reception of a control signal or the like when transmitting the data signal to each combination of the terminal station apparatuses 200 (overhead) ) Is calculated for each transmission method. Also, the overhead calculation unit 105 associates the calculated overhead with the modulation scheme, coding rate, and number of subcarriers used for transmission included in the data station in the terminal station apparatus 200 in association with each terminal station apparatus 200 combination. To be stored in the storage unit 106.

  Parameters necessary for calculating the transmission rate such as the overhead, modulation method, coding rate, number of subcarriers, etc. for each combination of terminal stations 200 in each transmission method are input from the external network via the network interface 104. When it is determined, the overhead calculation unit 105 causes the storage unit 106 to store the input parameter.

  The storage unit 106 stores the combination of the terminal station devices 200 and the overhead for each transmission method, the modulation method for each of the terminal station devices 200, the coding rate, and the number of subcarriers used for transmission.

The TDMA transmission rate calculation unit 107 stores the overhead of a control signal, etc. when transmitting using TDMA transmission, the data length of the data signal to be transmitted, the modulation scheme, the coding rate, and the number of subcarriers used for transmission Read from the unit 106. The TDMA transmission rate calculation unit 107 uses the parameters read from the storage unit 106 to calculate the transmission rate R ^TDMA in TDMA transmission using the following equation (1). The TDMA transmission rate calculation unit 107 outputs the calculated transmission rate R ^TDMA to the transmission method selection unit 109.

In equation (1), T _data is the data length and the unit is time. T _o ^TDMA is the overhead length of such control signals in the case of using the TDMA transmission. m is a number for identifying the terminal station apparatus 200 (m = 1, 2,..., N). N _{sub, m} is the number of subcarriers assigned to the m-th terminal station apparatus 200. C _m is a coding rate when a data signal addressed to the m-th terminal station apparatus 200 is transmitted. M _m is a modulation multilevel index when transmitting a data signal addressed to the m-th terminal station apparatus 200. T _s is the OFDM symbol length. All these parameters are parameters when TDMA transmission is used.

FIG. 3 is a diagram illustrating the overhead length of TDMA transmission in the wireless communication system according to the first embodiment. As shown in FIG. 3, the overhead length T _o ^TDMA is the total time of CS, BA, and intervals between frames, and is calculated by the following equation (2).

In Expression (2), _TCS is a carrier sense time. T _SIFS is SIFS (Short InterFrame Space) time defined in the wireless LAN system. T _BA is the transmission time of the response belief signal.

The OFDMA transmission rate calculation unit 108 stores the overhead of a control signal, etc. when transmitting using OFDMA transmission, the data length of the data signal to be transmitted, the modulation method, the coding rate, and the number of subcarriers used for transmission Read from the unit 106. The OFDMA transmission rate calculation unit 108 uses each parameter read from the storage unit 106 to calculate the transmission rate R ^OFDMA in OFDMA transmission using the following equation (3). The OFDMA transmission rate calculation unit 108 outputs the calculated law rate R ^OFDMA to the transmission method selection unit 109.

In Equation (3), T _data is the data length and the unit is time. T _o ^OFDMA is overhead length of such control signals in the case of using the OFDMA transmission. m is a number for identifying the terminal station apparatus 200 (m = 1, 2,..., N). N _{sub, m} is the number of subcarriers assigned to the m-th terminal station apparatus 200. C _m is a coding rate when a data signal addressed to the m-th terminal station apparatus 200 is transmitted. M _m is a modulation multilevel index when transmitting a data signal addressed to the m-th terminal station apparatus 200. T _s is the OFDM symbol length. All these parameters are parameters when OFDMA transmission is used.

FIG. 4 is a diagram illustrating the overhead length of OFDMA transmission in the wireless communication system according to the first embodiment. In the example illustrated in FIG. 4, a case where the wireless communication system includes two terminal station apparatuses 200 (200-1 and 200-2) is illustrated. As shown in FIG. 4, the overhead length T _o ^OFDMA is the total time of CS, BA, BAR, and intervals between frames, and is calculated by the following equation (4).

In the equation (4), T _BAR is the transmission time of the response belief request signal. When the wireless communication system includes N terminal station devices 200, the overhead length T _o ^OFDMA is calculated by the following equation (5).

The transmission method selection unit 109 inputs the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107 and the transmission rate R ^OFDMA calculated by the OFDMA transmission rate calculation unit 108. The transmission method selection unit 109 compares the transmission rate R ^TDMA with the transmission rate R ^OFDMA and selects a wireless transmission method with a high transmission rate. Transmission scheme selection section 109 outputs a selection signal indicating the selection result to TDMA transmission signal generation section 110 and OFDMA transmission signal generation section 111.

  The TDMA transmission signal generation unit 110 inputs a data signal from the network interface 104 and inputs a selection signal from the transmission method selection unit 109. When the selection signal indicates TDMA transmission, the TDMA transmission signal generation unit 110 converts the data signal addressed to any one of the terminal station devices 200 from the data signals addressed to the plurality of terminal station devices 200 to the radio packet signal. Modulate to The TDMA transmission signal generation unit 110 adds an identification signal indicating that the wireless packet signal is a wireless packet signal corresponding to the TDMA transmission method to the wireless packet signal obtained by the modulation. TDMA transmission signal generation section 110 outputs radio packet signals including an identification signal to transmission sections 112-1 to 112-N. In addition, when the selection signal does not indicate the TDMA transmission method, the TDMA transmission signal generation unit 110 outputs a wireless packet signal to the transmission units 112-1 to 112-N without performing processing on the input data signal. Absent.

  The OFDMA transmission signal generation unit 111 receives a data signal from the network interface 104 and receives a selection signal from the transmission method selection unit 109. When the selection signal indicates OFDMA transmission, the OFDMA transmission signal generation unit 111 modulates each of the input data signals addressed to the plurality of terminal station devices 200 into radio packet signals using different frequency bands. The OFDMA transmission signal generation unit 111 adds an identification signal indicating that the wireless packet signal is a wireless packet signal corresponding to the OFDMA transmission method to the wireless packet signal obtained by modulation. The OFDMA transmission signal generation unit 111 outputs radio packet signals including the identification signal to the transmission units 112-1 to 112-N. In addition, when the selection signal does not indicate the OFDMA transmission scheme, the OFDMA transmission signal generation unit 111 performs the output of the wireless packet signal to the transmission units 112-1 to 112 -N without performing the processing on the input data signal. Absent.

  Similarly to the receiving units 102-1 to 102-N, each of the transmitting units 112-1 to 112-N is connected to one of the antennas 101-1 to 101-N on a one-to-one basis. That is, one receiving unit 102 and one transmitting unit 112 are connected to each of the antennas 101-1 to 101 -N. The transmission units 112-1 to 112 -N convert the radio packet signal input from either the TDMA transmission signal generation unit 110 or the OFDMA transmission signal generation unit 111 into a frequency defined by the radio communication system ( A radio signal is generated by performing up-conversion and adjusting transmission power. The transmission units 112-1 to 112-N transmit the generated radio signals from the antennas 101-1 to 101-N.

  FIG. 5 is a block diagram illustrating a configuration of the terminal station apparatus 200 according to the first embodiment. As illustrated in FIG. 5, the terminal station apparatus 200 includes an antenna 201, a reception unit 202, a transmission method determination unit 203, a demodulation unit 204, a network interface 205, a modulation unit 206, and a transmission unit 207.

The receiving unit 202 transmits a signal obtained by performing frequency conversion (down-conversion), adjustment of received power, or the like to the reception signal received via the antenna 201 to the transmission method determination unit 203 and the demodulation unit 204. Output.
The transmission method determination unit 203 detects an identification signal included in the signal input from the reception unit 202 and outputs the detected identification signal to the demodulation unit 204.

  The demodulator 204 receives the identification signal from the transmission method determination unit 203. The demodulator 204 switches the demodulation process based on the transmission method indicated by the identification signal. The demodulation unit 204 performs demodulation on the signal input from the reception unit 202 according to the transmission method indicated by the identification signal. The demodulator 204 outputs the data signal obtained by the demodulation to the network interface 205.

  The network interface 205 converts the data signal input from the demodulator 204 into a packet format used in an external network, and transmits the packet format to the external network. The network interface 205 converts a packet received / received from an external network into a data signal and outputs the data signal to the modulation unit 206.

  Modulating section 206 modulates the data signal input from network interface 205 into a wireless packet signal in a format defined in the wireless communication system, and outputs the wireless packet signal obtained by the modulation to transmitting section 207.

  The transmission unit 207 generates a radio signal by performing conversion (up-conversion) to a frequency defined by the radio communication system, adjustment of transmission power, and the like on the radio packet signal input from the modulation unit 206. The transmission unit 207 transmits the generated radio signal from the antenna 201.

FIG. 6 is a flowchart illustrating a transmission method selection process performed by the base station apparatus 100 according to the first embodiment. When the transmission method selection process is started in the base station apparatus 100, the TDMA transmission rate calculation unit 107 reads out and acquires each parameter used when calculating the transmission rate R ^TDMA in TDMA transmission from the storage unit 106 (step S101). ).

The TDMA transmission rate calculation unit 107 calculates a transmission rate R ^TDMA in TDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^TDMA to the transmission method selection unit 109 (step S102).

The OFDMA transmission rate calculation unit 108 reads and acquires each parameter used when calculating the transmission rate R ^OFDMA in OFDMA transmission from the storage unit 106 (step S103).

The OFDMA transmission rate calculation unit 108 calculates a transmission rate R ^OFDMA in OFDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^OFDMA to the transmission method selection unit 109 (step S104).

The transmission method selection unit 109 compares the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107 with the transmission rate R ^OFDMA calculated by the OFDMA transmission rate calculation unit 108 (step S105).

When the value of the transmission rate R ^TDMA is equal to or greater than the value of the transmission rate R ^OFDMA (step S105: YES), the transmission method selection unit 109 selects that the base station device 100 uses TDMA transmission for transmission to the terminal station device 200. Then (step S106), the process proceeds to step S108.

When the value of the transmission rate R ^TDMA is less than the value of the transmission rate R ^OFDMA (step S105: NO), the transmission method selection unit 109 selects that the base station device 100 uses OFDMA transmission for transmission to the terminal station device 200. (Step S107), and the process proceeds to Step S108.

  The transmission method selection unit 109 generates a selection signal indicating a transmission method (either TDMA transmission or OFDMA transmission) used by the base station device 100 for transmission to the terminal station device 200, and generates the generated selection signal as a TDMA transmission signal. Output to unit 110 and OFDMA transmission signal generation unit 111 (step S108), and the transmission method selection processing is terminated.

  6 shows a procedure in which the OFDMA transmission rate calculation unit 108 calculates the transmission rate after the TDMA transmission rate calculation unit 107 calculates the transmission rate, the TDMA transmission rate calculation unit 107 and the OFDMA transmission rate calculation unit. The transmission rate may be calculated in parallel with 108.

  Depending on the selection signal output from the transmission method selection unit 109, either the TDMA transmission signal generation unit 110 or the OFDMA transmission signal generation unit 111 converts the data signal output from the network interface 104 into a wireless packet signal and transmits it. Output to the units 112-1 to 112 -N. The transmission method selection unit 109 selects a transmission method based on the expected value of the actual transmission rate calculated from each parameter, so that data is transmitted to the terminal station apparatus 200 using one of a plurality of transmission methods. It is possible to select a transmission method for improving the transmission speed at the time of transmission.

[Second Embodiment]
The radio communication system in the second embodiment is different from the base station apparatus 100 and the terminal station apparatus 200 included in the radio communication system (FIG. 1) in the first embodiment in the base station apparatus 300 shown in FIG. The terminal station apparatus 400 shown is provided. That is, the radio communication system according to the second embodiment described below includes a base station device 300 and a plurality of terminal station devices 400.

  FIG. 7 is a block diagram illustrating a configuration example of the base station apparatus 300 in the second embodiment. Base station apparatus 300 includes antennas 101-1 to 101-N, receiving units 102-1 to 102-N, demodulating unit 321, network interface 104, overhead calculating unit 105, storage unit 106, TDMA transmission rate calculating unit 107, SDMA. A transmission rate calculation unit 322, a transmission method selection unit 323, a TDMA transmission signal generation unit 110, an SDMA transmission signal generation unit 324, a transmission weight calculation unit 325, and a weight calculation unit 326 are provided.

  The base station apparatus 300 includes a demodulator 321 instead of the demodulator 103, a SDMA transmission rate calculator 322 instead of the OFDMA transmission rate calculator 108, and a transmission scheme instead of the transmission scheme selector 109. The first embodiment includes a selection unit 323, a point provided with an SDMA transmission signal generation unit 324 instead of the OFDMA transmission signal generation unit 111, and a transmission weight calculation unit 325 and a weight calculation unit 326. Different from base station apparatus 100 (FIG. 2). In the base station apparatus 300, the overhead calculation unit 105 causes the storage unit 106 to store parameters related to TDMA transmission and SDMA transmission. In the base station apparatus 300, the same reference numerals are given to the same functional units as those included in the base station apparatus 100, and the description thereof is omitted.

  The demodulator 321 demodulates the signals input from the receivers 102-1 to 102-N and outputs the acquired data signal to the network interface 104. Demodulation section 321 detects propagation channel information from the data signal acquired by demodulation, and outputs the detected propagation channel information to transmission weight calculation section 325.

The SDMA transmission rate calculation unit 322 stores overhead such as control signals, transmission data signal data length, modulation method, coding rate, and number of subcarriers used for transmission when transmission is performed using SDMA transmission. Read from the unit 106. The SDMA transmission rate calculation unit 322 uses the parameters read from the storage unit 106 to calculate the transmission rate R ^SDMA in SDMA transmission using the following equation (6). The SDMA transmission rate calculation unit 322 outputs the calculated transmission rate R ^SDMA to the transmission method selection unit 323.

In equation (6), T _data is the data length and the unit is time. T _o ^SDMA is overhead length of such control signals in the case of using the SDMA transmission. m is a number for identifying the terminal station device 400 (m = 1, 2,..., N). N _{sub, m} is the number of subcarriers assigned to the m-th terminal station device 400. C _m is a coding rate when a data signal addressed to the m-th terminal station device 400 is transmitted. M _m is a modulation multi-level index when transmitting a data signal addressed to the m-th terminal station device 400. T _s is the OFDM symbol length. All these parameters are parameters when SDMA transmission is used.

FIG. 8 is a diagram illustrating the overhead length of SDMA transmission in the wireless communication system according to the second embodiment. In the example shown in FIG. 8, the case where a radio | wireless communications system is provided with the two terminal station apparatuses 400 (400-1, 400-2) is shown. Overhead length _T ^{o SDMA,} as shown in FIG. 8, a CS and NDPA and NDP and BR and BRP and BA and BAR and time obtained by adding the interval between each frame is calculated by the following equation (7).

In formula (7), TNDPA is the transmission time of the NDP signal transmission notification signal. TNDP is a transmission time of an NDP signal for estimating a propagation channel. TBR is a transmission time of a signal for notifying propagation channel information. TBRP is a transmission time of a request signal for having propagation channel information transmitted. The wireless communication system in the case of providing the N of terminal station apparatus 400, the overhead length _T ^{o SDMA} is calculated by the following equation (8).

The transmission method selection unit 323 inputs the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107 and the transmission rate R ^SDMA calculated by the SDMA transmission rate calculation unit 322. The transmission method selection unit 323 compares the transmission rate R ^TDMA with the transmission rate R ^SDMA and selects a wireless transmission method with a high transmission rate. Transmission scheme selection section 323 outputs a selection signal indicating the selection result to TDMA transmission signal generation section 110 and SDMA transmission signal generation section 324.

  The SDMA transmission signal generation unit 324 receives a data signal from the network interface 104 and receives a selection signal from the transmission method selection unit 323. When the selection signal indicates SDMA transmission, the SDMA transmission signal generation unit 324 modulates the input data signal into a transmission signal for each terminal station device 400. The SDMA transmission signal generation unit 324 adds an identification signal indicating that the wireless packet signal is a wireless packet corresponding to the SDMA transmission method to the transmission signal obtained by modulation. SDMA transmission signal generation section 324 outputs a transmission signal including the identification signal to weight calculation section 326. In addition, when the selection signal does not indicate the SDMA transmission method, the SDMA transmission signal generation unit 324 does not process the input data signal and does not output the transmission signal to the weight calculation unit 326.

  The transmission weight calculation unit 325 calculates a transmission weight corresponding to each terminal station device 400 based on the propagation channel information input from the demodulation unit 321. The transmission weight calculation unit 325 outputs the calculated transmission weight of each terminal station device 400 to the weight calculation unit 326. As a method for the transmission weight calculation unit 325 to calculate the transmission weight, either linear calculation or non-linear calculation is used. Examples of the linear calculation include a ZF (Zero Forcing) method and an MMSE (Minimum Mean Squared Error) method. Nonlinear operations include, for example, a THP (Tomlinson Harashima Precoding) method and a VP (Vector Perturbation) method. When the transmission weight calculation unit 325 calculates the transmission weight, a method other than the above-described method may be used.

  The weight calculator 326 multiplies the transmission signal input from the SDMA transmission signal generator 324 by the transmission weight input from the transmission weight calculator 325 to generate a radio packet signal. When generating the radio packet signal, the weight calculation unit 326 multiplies the transmission signal by the transmission weight corresponding to the terminal station device 400 that is the destination of the transmission signal to be multiplied among the input transmission weights. The weight calculation unit 326 outputs the generated wireless packet signal to the transmission units 112-1 to 112-N.

FIG. 9 is a block diagram illustrating a configuration example of the terminal station apparatus 400 according to the second embodiment.
The terminal station apparatus 400 includes an antenna 201, a reception unit 202, a demodulation unit 404, a network interface 205, a propagation channel information acquisition unit 408, a modulation unit 406, and a transmission unit 207.

  The terminal station device 400 does not include the transmission method determination unit 203, includes a propagation channel information acquisition unit 408, includes a demodulation unit 404 instead of the demodulation unit 204, and a modulation unit 206. It differs from the terminal station apparatus 200 of 1st Embodiment in the point provided with the modulation | alteration part 406 instead. In the terminal station device 400, the same functional units as those provided in the terminal station device 200 are denoted by the same reference numerals and description thereof is omitted.

  The demodulator 404 demodulates a data signal or the like from the signal input from the receiver 202. Demodulation section 404 outputs the demodulated data signal to network interface 205. Demodulation section 404 outputs NDP (null data packet) included in the input signal to propagation channel information acquisition section 408.

  Propagation channel information acquisition section 408 estimates propagation channel information in a propagation channel between the own apparatus and base station apparatus 300 based on NDP input from demodulation section 404. The propagation channel information acquisition unit 408 stores the estimated propagation channel information and outputs the estimated propagation channel information to the modulation unit 406.

  The modulation unit 406 modulates the data signal input from the network interface 104 and the propagation channel information input from the propagation channel information acquisition unit 408 into a radio packet signal. Modulating section 406 outputs the radio packet signal obtained by the modulation to transmitting section 207.

FIG. 10 is a flowchart illustrating a transmission method selection process performed by the base station apparatus 300 according to the second embodiment. In the base station device 300, when the transmission method selection process is started, the TDMA transmission rate calculation unit 107 reads out and acquires each parameter used when calculating the transmission rate R ^TDMA in TDMA transmission from the storage unit 106 (step). S201).

The TDMA transmission rate calculation unit 107 calculates a transmission rate R ^TDMA in TDMA transmission based on each read parameter, and outputs the calculated transmission rate R ^TDMA to the transmission method selection unit 323 (step S202).

The SDMA transmission rate calculation unit 322 reads and acquires each parameter used when calculating the transmission rate R ^SDMA in SDMA transmission from the storage unit 106 (step S203).

The SDMA transmission rate calculation unit 322 calculates a transmission rate R ^SDMA in SDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^SDMA to the transmission method selection unit 323 (step S204).

The transmission method selection unit 323 compares the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107 with the transmission rate R ^SDMA calculated by the SDMA transmission rate calculation unit 322 (step S205).

When the value of the transmission rate R ^TDMA is equal to or greater than the value of the transmission rate R ^SDMA (step S205: YES), the transmission method selection unit 323 selects that the base station device 300 uses TDMA transmission for transmission to the terminal station device 400. (Step S206), and the process proceeds to Step S208.

When the value of the transmission rate R ^TDMA is less than the value of the transmission rate R ^SDMA (step S205: NO), the transmission method selection unit 323 selects that the base station device 300 uses SDMA transmission for transmission to the terminal station device 400. (Step S207), and the process proceeds to Step S208.

  The transmission method selection unit 323 generates a selection signal indicating a transmission method (either TDMA transmission or SDMA transmission) used by the base station device 300 for transmission to the terminal station device 400, and generates the generated selection signal as a TDMA transmission signal. Unit 110 and SDMA transmission signal generation unit 324 (step S208), and the transmission method selection process is terminated.

  As described above, according to the selection signal output from the transmission method selection unit 323, either the TDMA transmission signal generation unit 110 or the SDMA transmission signal generation unit 324 outputs the data signal output from the network interface 104 as a wireless packet signal. And output to the transmitters 112-1 to 112 -N. The transmission method selection unit 323 selects a transmission method based on an expected value of an actual transmission rate calculated from each parameter, so that data is transmitted to the terminal station apparatus 400 using one of a plurality of transmission methods. It is possible to select a transmission method for improving the transmission speed at the time of transmission.

  10 shows a procedure in which the SDMA transmission rate calculation unit 322 calculates the transmission rate after the TDMA transmission rate calculation unit 107 calculates the transmission rate. However, the TDMA transmission rate calculation unit 107 and the SDMA transmission signal generation unit The transmission rate may be calculated in parallel with H.324.

[Third Embodiment]
The radio communication system according to the third embodiment is different from the base station apparatus 100 and the terminal station apparatus 200 included in the radio communication system (FIG. 1) according to the first embodiment in the base station apparatus 500 and FIG. A terminal station device 600 shown in FIG. That is, the radio communication system according to the third embodiment described below includes a base station device 500 and a plurality of terminal station devices 600.

  FIG. 11 is a block diagram illustrating a configuration example of the base station device 500 according to the third embodiment. Base station apparatus 500 includes antennas 101-1 to 101-N, reception units 102-1 to 102-N, demodulation unit 321, network interface 104, overhead calculation unit 105, storage unit 106, TDMA transmission rate calculation unit 107, OFDMA. Transmission rate calculation unit 108, SDMA transmission rate calculation unit 322, transmission method selection unit 531, TDMA transmission signal generation unit 110, OFDMA transmission signal generation unit 111, SDMA transmission signal generation unit 324, transmission weight calculation unit 325, weight calculation unit 326 And transmission units 112-1 to 112 -N.

  The base station apparatus 500 differs from the base station apparatus 100 (FIG. 1) of the first embodiment in the following points. Base station apparatus 500 includes a demodulation unit 321 instead of demodulation unit 103, a transmission system selection unit 531 instead of transmission method selection unit 109, and an SDMA transmission rate calculation unit 322 and an SDMA transmission signal generation unit. The base station apparatus 100 is different from the base station apparatus 100 in that a transmission weight calculation unit 325 and a weight calculation unit 326 are further provided. In base station apparatus 500, overhead calculation section 105 stores each parameter regarding TDMA transmission, OFDMA transmission, and SDMA transmission in storage section 106. In the base station device 500, the same functional units as those included in the base station device 100 of the first embodiment or the base station device 300 (FIG. 7) of the second embodiment are denoted by the same reference numerals and described. Is omitted.

The transmission method selection unit 531 includes the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107, the transmission rate R ^OFDMA calculated by the OFDMA transmission rate calculation unit 108, and the transmission rate R ^SDMA calculated by the SDMA transmission rate calculation unit 322. Enter. The transmission method selection unit 531 compares the transmission rate R ^TDMA , the transmission rate R ^OFDMA, and the transmission rate R ^SDMA, and selects a radio transmission method with a high transmission rate. The transmission scheme selection unit 531 outputs a selection signal indicating the selection result to the TDMA transmission signal generation unit 110, the OFDMA transmission signal generation unit 111, and the SDMA transmission signal generation unit 324.

  FIG. 12 is a block diagram illustrating a configuration example of the terminal station apparatus 600 according to the third embodiment. The terminal station device 600 includes an antenna 201, a reception unit 202, a transmission method determination unit 203, a demodulation unit 604, a network interface 205, a propagation channel information acquisition unit 408, a modulation unit 406, and a transmission unit 207.

  The terminal station device 600 is different from the terminal station device 400 of the second embodiment in that a demodulating unit 604 is provided instead of the demodulating unit 404 and a transmission method determining unit 203 is further provided. In the terminal station device 600, the same reference numerals are given to the same functional units as those included in the terminal station device 200 (FIG. 5) of the first embodiment or the terminal station device 400 (FIG. 9) of the second embodiment. A description thereof will be omitted.

  Demodulation section 604 receives the identification signal from transmission method determination section 203. Demodulation section 604 switches demodulation processing based on the transmission method indicated by the identification signal. The demodulator 604 performs demodulation on the signal input from the receiver 202 according to the transmission method indicated by the identification signal. Demodulation section 604 outputs the data signal obtained by demodulation to network interface 205. Demodulation section 604 outputs NDP (null packet data) included in the input signal to propagation channel information acquisition section 408.

FIG. 13 is a flowchart illustrating a transmission method selection process performed by the base station device 500 according to the third embodiment. In the base station device 500, when the transmission method selection process is started, the TDMA transmission rate calculation unit 107 reads out and acquires each parameter used when calculating the transmission rate R ^TDMA in TDMA transmission from the storage unit 106 (step). S301).

The TDMA transmission rate calculation unit 107 calculates a transmission rate R ^TDMA in TDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^TDMA to the transmission method selection unit 531 (step S302).

The OFDMA transmission rate calculation unit 108 reads and acquires each parameter used when calculating the transmission rate R ^OFDMA in OFDMA transmission from the storage unit 106 (step S303).

The OFDMA transmission rate calculation unit 108 calculates a transmission rate R ^OFDMA in OFDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^OFDMA to the transmission method selection unit 531 (step S304).

The SDMA transmission rate calculation unit 322 reads and acquires each parameter used when calculating the transmission rate R ^SDMA in SDMA transmission from the storage unit 106 (step S305).

The SDMA transmission rate calculation unit 322 calculates a transmission rate R ^SDMA in SDMA transmission based on the read parameters, and outputs the calculated transmission rate R ^SDMA to the transmission method selection unit 531 (step S306).

The transmission method selection unit 531 compares the transmission rate R ^TDMA calculated by the TDMA transmission rate calculation unit 107 with the transmission rate R ^OFDMA calculated by the OFDMA transmission rate calculation unit 108 (step S307).

When the value of the transmission rate R ^TDMA is equal to or greater than the value of the transmission rate R ^OFDMA (step S307: YES), the transmission method selection unit 531 selects that the base station device 500 uses TDMA transmission for transmission to the terminal station device 600. (Step S308), and the process proceeds to Step S312.

When the value of the transmission rate R ^TDMA is less than the value of the transmission rate R ^OFDMA (step S307: NO), the transmission method selection unit 531 includes the transmission rate R ^OFDMA calculated by the OFDMA transmission rate calculation unit 108 and the SDMA transmission rate calculation unit. The transmission rate R ^SDMA calculated by 322 is compared (step S309).

When the value of the transmission rate R ^OFDMA is equal to or greater than the value of the transmission rate R ^SDMA (step S309: YES), the transmission method selection unit 531 indicates that the base station device 500 uses OFDMA transmission for transmission to the terminal station device 600. Select (step S310), and the process proceeds to step S312.

When the value of the transmission rate R ^OFDMA is less than the value of the transmission rate R ^SDMA (step S309: NO), the transmission method selection unit 531 indicates that the base station device 500 uses SDMA transmission for transmission to the terminal station device 600. Select (step S311), and the process proceeds to step S312.

  The transmission method selection unit 531 generates a selection signal indicating a transmission method (TDMA transmission, OFDMA transmission, or SDMA transmission) used by the base station device 500 for transmission to the terminal station device 600. The transmission method selection unit 531 outputs the generated selection signal to the TDMA transmission signal generation unit 110, the OFDMA transmission signal generation unit 111, and the SDMA transmission signal generation unit 324 (step S312), and ends the transmission method selection processing.

  As described above, one of the TDMA transmission signal generation unit 110, the OFDMA transmission signal generation unit 111, and the SDMA transmission signal generation unit 324 is output from the network interface 104 according to the selection signal output from the transmission method selection unit 531. The data signal to be converted is converted into a wireless packet signal and output to the transmitters 112-1 to 112 -N. The transmission method selection unit 531 selects a transmission method based on the expected value of the actual transmission rate calculated from each parameter, so that data is transmitted to the terminal station apparatus 600 using one of a plurality of transmission methods. It is possible to select a transmission method for improving the transmission speed at the time of transmission.

Although FIG. 13 shows a procedure for calculating the transmission rate R ^TDMA , the transmission rate R ^OFDMA , and the transmission rate R ^SDMA in this order, the transmission rates may be calculated in parallel.

[Fourth Embodiment]
The radio communication system according to the fourth embodiment replaces the base station apparatus 100 and the terminal station apparatus 200 included in the radio communication system (FIG. 1) according to the first embodiment, and the base station apparatus 700 and FIG. The terminal station device 400 shown in FIG. That is, the wireless communication system in the fourth embodiment described below includes a base station device 700 and a plurality of terminal station devices 400.

  FIG. 14 is a block diagram illustrating a configuration example of the base station apparatus 700 according to the fourth embodiment. Base station apparatus 700 includes antennas 101-1 to 101-N, reception units 102-1 to 102-N, demodulation unit 321, network interface 104, overhead calculation unit 105, storage unit 106, TDMA transmission rate calculation unit 107, SDMA. A transmission rate calculation unit 743, a transmission method selection unit 323, a TDMA transmission signal generation unit 110, an SDMA transmission signal generation unit 324, a transmission weight calculation unit 325, a weight calculation unit 326, a propagation channel storage unit 741, a propagation channel correlation calculation unit 742, And the transmission parts 112-1 to 112-N are provided.

  The base station apparatus 700 is different from the base station apparatus 300 (FIG. 7) of the second embodiment in the following points. Base station apparatus 700 is different from base station apparatus 300 in that it includes an SDMA transmission rate calculation unit 743 instead of SDMA transmission rate calculation unit 322 and a propagation channel storage unit 741 and a propagation channel correlation calculation unit 742. . The propagation channel information output from the demodulation unit 321 is also input to the propagation channel storage unit 741 and the propagation channel correlation calculation unit 742. In the base station apparatus 700, the functional units included in the base station apparatus 100 (FIG. 2) of the first embodiment, the base station apparatus 300 of the second embodiment, or the base station apparatus 500 (FIG. 11) of the third embodiment. The same functional parts as those in FIG.

  The propagation channel storage unit 741 stores the propagation channel information output from the demodulation unit 321. In the propagation channel storage unit 741, the propagation channel information is stored in association with each combination of the terminal station device 400 and the subcarriers included in the wireless communication system.

  Based on the propagation channel information input from the demodulation unit 321 and the propagation channel information stored in the propagation channel storage unit 741, the propagation channel correlation calculation unit 742 calculates the correlation between subcarriers by the following equation (9). It calculates for every terminal station apparatus 400.

In Equation (9), S is a correlation value. A is the number of rows in the propagation channel information _{Hd, k} . B is the number of columns in the propagation channel information _{Hd, k} . h _{d, k, a, b} are elements of a row and b column in the propagation channel information H _{d, k} . Propagation channel information H _{d, k} is transmission channel information of subcarrier number k between base station apparatus 700 and d-th terminal station apparatus 400. In addition, h _{d, k, a, b} (hereinafter referred to as ^ h _{d, k, a, b} ) with “^ (hat)” attached thereon is propagation channel information ^ H _{d, k.} Element of row a and column b. The propagation channel information ^ H _{d, k} is propagation channel information stored in the propagation channel storage unit 741. The propagation channel information H _{d, k} is propagation channel information input from the demodulation unit 321.

  The propagation channel correlation calculation unit 742 outputs the calculated correlation value S to the SDMA transmission rate calculation unit 743. Note that the propagation channel correlation calculation unit 742 uses the propagation channel information input from the demodulation unit 321 without using the propagation channel information stored in the propagation channel storage unit 741 as shown in the equation (9). Thus, the correlation value S may be calculated.

The SDMA transmission rate calculation unit 743 stores the overhead such as a control signal when transmitting using SDMA transmission, the data length of the data signal to be transmitted, the modulation method, the coding rate, and the number of subcarriers used for transmission. Read from the unit 106. The SDMA transmission rate calculation unit 743 calculates a transmission rate R ^SDMA in SDMA transmission by the following equation (10) based on each parameter read from the storage unit 106 and the correlation value calculated by the propagation channel correlation calculation unit 742. To do.

In the equation (10), α is a value between 0 and 1, and is a value determined corresponding to the correlation value S. The value of α is determined according to the correlation value S so that the higher the correlation value S, the smaller the value of the coefficient α, and the lower the correlation value S, the larger the value of the coefficient α. That is, the SDMA transmission rate calculation unit 743 sets the transmission rate R ^SDMA reflecting the correlation value S calculated by the propagation channel correlation calculation unit 742, that is, the state of the propagation channel information between the base station device 700 and the terminal station device 400. calculate.

Since the transmission method selection process performed by the base station apparatus 700 in the fourth embodiment is the same as the transmission method selection process (FIG. 10) performed by the base station apparatus 300 in the second embodiment, description thereof is omitted. As described above, the base station apparatus 700 can calculate the transmission rate R ^SDMA that reflects the state of the propagation channel information between the base station apparatus 700 and the terminal station apparatus 400, and a plurality of transmission rates R ^SDMA can be calculated based on parameters or the like. The accuracy of selecting a transmission method that improves the transmission speed from the transmission method can be improved.

[Fifth Embodiment]
The radio communication system in the fifth embodiment is different from the base station apparatus 100 and the terminal station apparatus 200 included in the radio communication system (FIG. 1) in the first embodiment in the base station apparatus 800 and FIG. The terminal station device 600 shown is provided. That is, the radio communication system according to the fifth embodiment described below includes a base station device 800 and a plurality of terminal station devices 600.

  FIG. 15 is a block diagram illustrating a configuration example of the base station apparatus 800 according to the fifth embodiment. Base station apparatus 800 includes antennas 101-1 to 101-N, reception units 102-1 to 102-N, demodulation unit 321, network interface 104, overhead calculation unit 105, storage unit 106, TDMA transmission rate calculation unit 107, OFDMA. Transmission rate calculation unit 108, SDMA transmission rate calculation unit 743, transmission method selection unit 531, TDMA transmission signal generation unit 110, OFDMA transmission signal generation unit 111, SDMA transmission signal generation unit 324, transmission weight calculation unit 325, weight calculation unit 326 , A propagation channel storage unit 741, a propagation channel correlation calculation unit 742, and transmission units 112-1 to 112-N.

  The base station apparatus 800 differs from the base station apparatus 700 (FIG. 14) of the fourth embodiment in the following points. The base station apparatus 800 is different from the base station apparatus 700 in that a transmission system selection unit 531 is provided instead of the transmission system selection unit 323 and that an OFDMA transmission rate calculation unit 108 and an OFDMA transmission signal generation unit 111 are further provided. In the base station apparatus 800, the base station apparatus 100 (FIG. 2) of the first embodiment, the base station apparatus 300 (FIG. 7) of the second embodiment, and the base station apparatus 500 (FIG. 11) of the third embodiment. Alternatively, the same functional units as the functional units included in the base station device 700 of the fourth embodiment are denoted by the same reference numerals and description thereof is omitted.

Similarly to the base station apparatus 700 of the fourth embodiment, the base station apparatus 800 in the fifth embodiment calculates the transmission rate R ^SDMA according to the correlation value S, and the transmission method selection unit 531 transmits the transmission rate R ^TDMA. The transmission rate R ^OFDMA and the transmission rate R ^SDMA are compared. The transmission method selection process performed by the base station device 800 is the same as the transmission method selection processing (FIG. 13) performed by the base station device 500 in the third embodiment, and thus description thereof is omitted.

The base station apparatus 800 can calculate the transmission rate R ^SDMA reflecting the state of propagation channel information between the base station apparatus 800 and the terminal station apparatus 600, and can transmit the transmission rate from a plurality of transmission schemes based on parameters and the like. It is possible to improve the accuracy of selecting a transmission method that improves the transmission rate.

  As described above, in the radio communication system of each embodiment, the base station apparatus that can transmit a data signal to the terminal station apparatus using a plurality of transmission schemes includes overhead such as a control signal, data length, modulation scheme, High-speed and highly efficient wireless communication can be realized by selecting a transmission method that maximizes the transmission speed from among a plurality of transmission methods based on the coding rate and transmission band information.

  Also, in the wireless communication systems of the fourth and fifth embodiments, overhead such as control signals, data length, modulation scheme, coding rate, and transmission band information, and between the base station apparatus and the terminal station apparatus Based on the correlation value of the propagation channel information, a transmission method with the maximum transmission rate is selected from among a plurality of transmission methods. Selection that reflects the state of the propagation channel information can be performed, and the accuracy of selecting a transmission method that maximizes the actual transmission rate can be improved.

  In each of the above-described embodiments, the base station apparatus performs processing for calculating a transmission rate according to each of a plurality of transmission schemes and processing for selecting one of the plurality of transmission schemes to generate a selection signal. The configuration to do is shown. However, a transmission system selection device for calculating a transmission rate and selecting a transmission method is provided in a wireless communication system separately from the base station device, and the base station device and the transmission method selection device are communicably connected to each other. The transmission method used in the above may be determined.

  You may make it implement | achieve the base station apparatus and terminal station apparatus in embodiment mentioned above with a computer. In that case, a program for realizing this function may be recorded on a computer-readable recording medium, and the program recorded on this recording medium may be read into a computer system and executed. Here, the “computer system” includes an OS and hardware such as peripheral devices. The “computer-readable recording medium” refers to a storage device such as a flexible medium, a magneto-optical disk, a portable medium such as a ROM and a CD-ROM, and a hard disk incorporated in a computer system. Further, the “computer-readable recording medium” is a program that dynamically holds a program for a short time, like a communication line when a program is transmitted via a network such as the Internet or a communication line such as a telephone line. In this case, a volatile memory inside a computer system serving as a server or a client in that case may be included and a program held for a certain period of time. Further, the program may be for realizing a part of the functions described above, and may be a program capable of realizing the functions described above in combination with a program already recorded in the computer system. It may be realized using hardware such as PLD (Programmable Logic Device) or FPGA (Field Programmable Gate Array).

  The embodiment of the present invention has been described in detail with reference to the drawings. However, the specific configuration is not limited to this embodiment, and includes designs and the like that do not depart from the gist of the present invention.

  In a base station apparatus or communication apparatus having a plurality of transmission methods, it can be applied to applications where it is indispensable to realize high-speed and highly efficient wireless communication.

100, 300, 500, 700, 800, 91 ... Base station apparatus 101-1, 101-N ... Antenna 102, 102-1, 102-N ... Receiver 103, 321 ... Demodulator 104 ... Network interface 105 ... Overhead calculation Unit 106 ... Storage unit 107 ... TDMA transmission rate calculation unit 108 ... OFDMA transmission rate calculation unit 109, 323, 531 ... Transmission method selection unit 110 ... TDMA transmission signal generation unit 111 ... OFDMA transmission signal generation unit 112, 112-1, 112 -N: transmission unit 322, 743 ... SDMA transmission rate calculation unit 324 ... SDMA transmission signal generation unit 325 ... transmission weight calculation unit 326 ... weight calculation unit 741 ... propagation channel storage unit 742 ... propagation channel correlation calculation unit 200, 200-1 , 200-2, 400, 600, 92-1 , 92-2 ... terminal station device 201 ... antenna 202 ... receiving unit 203 ... transmission method determining unit 204, 404, 604 ... demodulating unit 205 ... network interface 206, 406 ... modulating unit 207 ... transmitting unit 408 ... propagation channel information obtaining unit

Claims (7)

A wireless communication system comprising a base station device and a plurality of terminal station devices,
The base station device
When transmitting a data signal to the terminal station apparatus using any one of a plurality of transmission schemes, overhead including transmission and reception of control signals, data length of data signals, modulation schemes, coding rates, A transmission rate calculation unit that calculates a transmission rate for each transmission method based on the number of subcarriers used for transmission;
A transmission signal generation unit that modulates a data signal to be transmitted to the terminal station apparatus into a radio packet signal corresponding to each of the plurality of transmission methods;
A transmission method selection unit that selects the transmission signal generation unit to generate a radio packet signal according to a transmission method corresponding to the maximum transmission rate among the plurality of transmission rates calculated by the transmission rate calculation unit;
A wireless communication system comprising: a transmission unit that converts a wireless packet signal generated according to the selection by the transmission method selection unit into a wireless signal and transmits the wireless signal. The wireless communication system according to claim 1, wherein
The transmission rate calculator is
When transmitting a data signal to the terminal station apparatus using time division multiple access transmission, overhead including transmission / reception of a control signal, data length of the data signal, modulation scheme, coding rate, and sub used for transmission A time division multiple access transmission rate calculation unit for calculating a first transmission rate based on the number of carriers;
When transmitting a data signal to the terminal station apparatus using orthogonal frequency division multiple access transmission, overhead including transmission / reception of control signal, data length of data signal, modulation method, coding rate, and transmission are used. An orthogonal frequency division multiple access transmission rate calculator that calculates a second transmission rate based on the number of subcarriers;
Including
The transmission signal generator is
A time division multiple access transmission signal generation unit that modulates a data signal to be transmitted to the terminal station device into a radio packet signal corresponding to time division multiple access transmission;
An orthogonal frequency division multiple access transmission signal generating unit that modulates a data signal to be transmitted to the terminal station device into a radio packet signal corresponding to orthogonal frequency division multiple access transmission;
The transmission method selection unit
Which of the time division multiple access transmission signal generation unit and the orthogonal frequency division multiple access transmission signal generation unit generates the radio packet signal by comparing the first transmission rate and the second transmission rate A wireless communication system, characterized by being selected. The wireless communication system according to claim 1, wherein
The transmission rate calculator is
When transmitting a data signal to the terminal station apparatus using time division multiple access transmission, overhead including transmission / reception of a control signal, data length of the data signal, modulation scheme, coding rate, and sub used for transmission A time division multiple access transmission rate calculation unit for calculating a first transmission rate based on the number of carriers;
In the case of transmitting a data signal to the terminal station apparatus using space division multiple access transmission, overhead including transmission / reception of a control signal, data length of the data signal, modulation scheme, coding rate, and sub used for transmission A space division multiple access transmission rate calculation unit that calculates a second transmission rate based on the number of carriers;
Including
The transmission signal generator is
A time division multiple access transmission signal generation unit that modulates a data signal to be transmitted to the terminal station device into a radio packet signal corresponding to time division multiple access transmission;
A space division multiple access transmission signal generator that modulates a data signal to be transmitted to the terminal station device into a radio packet signal corresponding to space division multiple access transmission;
Including
The transmission method selection unit
The first transmission rate and the second transmission rate are compared, and the time division multiple access transmission signal generation unit or the space division multiple access transmission signal generation unit is selected to generate a radio packet signal A wireless communication system. The wireless communication system according to claim 3,
The transmission rate calculator is
When transmitting a data signal to the terminal station apparatus using orthogonal frequency division multiple access transmission, overhead including transmission / reception of control signal, data length of data signal, modulation method, coding rate, and transmission are used. An orthogonal frequency division multiple access transmission rate calculation unit for calculating a third transmission rate based on the number of subcarriers;
The transmission signal generator is
An orthogonal frequency division multiple access transmission signal generator that modulates a data signal to be transmitted to the terminal station apparatus into a radio packet signal corresponding to orthogonal frequency division multiple access transmission;
The transmission method selection unit
The time division multiple access transmission signal generator, the space division multiple access transmission signal generator, and the orthogonal frequency division multiple are compared by comparing the first transmission rate, the second transmission rate, and the third transmission rate. A radio communication system, characterized in that it selects which one of the connection transmission signal generation units generates a radio packet signal. In the radio | wireless communications system in any one of Claim 3 or Claim 4,
The terminal station device
A propagation channel information acquisition unit that acquires, for each subcarrier, propagation channel information between the own device and the base station device;
A terminal station transmitter that transmits the propagation channel information to the base station device;
With
The base station device
A propagation channel correlation calculating unit that calculates a correlation value between subcarriers for each of the terminal station devices using the propagation channel information received from the terminal station device;
The space division multiple access transmission rate calculation unit,
In the case of transmitting a data signal to the terminal station apparatus using space division multiple access transmission, overhead including transmission / reception of a control signal, data length of the data signal, modulation scheme, coding rate, and sub used for transmission The wireless communication system, wherein the second transmission rate is calculated based on the number of carriers and the correlation value. Overhead including transmission / reception of control signal, data length of data signal, modulation method, coding rate when data signal is transmitted to multiple terminal stations using any one of multiple transmission methods A transmission rate calculation unit that calculates a transmission rate for each transmission method based on the number of subcarriers used for transmission,
A transmission signal generation unit that modulates a data signal to be transmitted to the terminal station apparatus into a radio packet signal corresponding to each of the plurality of transmission methods;
A transmission method selection unit that selects the transmission signal generation unit to generate a radio packet signal according to a transmission method corresponding to the maximum transmission rate among the plurality of transmission rates calculated by the transmission rate calculation unit;
A wireless communication apparatus comprising: a transmission unit that converts a wireless packet signal generated according to selection by the transmission method selection unit into a wireless signal and transmits the wireless signal. A wireless communication method in a wireless communication system comprising a base station device and a plurality of terminal station devices,
When transmitting a data signal to the terminal station apparatus using any one of a plurality of transmission schemes, overhead including transmission and reception of control signals, data length of data signals, modulation schemes, coding rates, A transmission rate calculating step for calculating a transmission rate for each transmission method based on the number of subcarriers used for transmission;
A transmission method selection step for selecting a transmission method corresponding to the maximum transmission rate among the plurality of transmission rates calculated in the transmission rate calculation step;
A transmission signal generation step of modulating a data signal into a radio packet signal according to the transmission method selected in the transmission method selection step;
And a transmitting step of transmitting the radio packet signal after converting the radio packet signal into a radio signal.

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