JP2012238985A - Radio communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a communication system that can maintain communication quality even if a certain subcarrier is disturbed and suppress the power consumption of a terminal which is not a communication object.SOLUTION: A radio communication system performs radio communication between transmission and reception devices using a plurality of subcarriers. A baseband processing unit 36 of a transmission and reception device modulates transmission data, demodulates a received signal, and also detects reception quality of each carrier included in the received signal. A CPU 33 determines subcarriers to be used for transmission based on the reception quality of each detected carrier, and outputs the number of subcarriers to be used, and a modulation scheme and a coding rate at the time of transmission. A MAC processing unit 35 obtains a line usage period based on the modulation scheme, the coding rate, and the number of subcarriers to be used output from the CPU 33 at the time of transmission, generates a transmission frame including the line usage period and transmits to the baseband processing unit 36.

Description

  The present invention relates to an OFDM (Orthogonal Frequency Division Multiplexing) modulation wireless communication system, and in particular, can perform stable communication according to a propagation path condition and reduce power consumption of a wireless transmission / reception apparatus. The present invention relates to a wireless communication system.

[Description of Prior Art]
As a modulation method used in digital wireless communication between mobile terminals such as a wireless LAN (Local Area Network) and a wireless PAN (Personal Area Network), there is OFDM.
OFDM is adopted in the physical layer wireless transmission system of the IEEE 802.11a / g standard in the IEEE 802.11 wireless LAN.

  Since OFDM divides high-speed data into a plurality of low-speed data strings and performs parallel transmission using a plurality of subcarriers, the symbol time of each subcarrier signal is r. m. It becomes relatively longer than the s delay spread, and the influence of multipath distortion can be reduced. r. m. The s delay spread is a comprehensive index indicating the characteristic of the delay profile indicating the relationship between the delay time and the level of the incoming wave (including the direct wave and the delayed wave).

  OFDM is multicarrier modulation using a plurality of subcarriers, and distortion is hardly generated in the reception signal spectrum of each subcarrier, and deterioration of the reception signal occurs only as a decrease in level. Therefore, good characteristics can be realized by combination with error correction.

  In addition, by inserting a guard interval as a redundant time to reduce interference due to multipath, interference of multipath delay waves can be avoided efficiently, and excellent communication quality can be achieved even in a multipath propagation environment. It is obtained.

  Multipath propagation is a propagation environment in which a transmission wave transmitted from a transmission antenna arrives at a reception antenna through multiple (multi) paths (paths), and limits the increase in the transmission speed of the wireless LAN. Has become the biggest factor.

According to the IEEE802.11a standard, the OFDM signal has 52 subcarriers.
Among these, 4 subcarriers are used for transmission of pilot signals necessary for correction of phase rotation for reception, and data signals are transmitted on the remaining 48 subcarriers. In one subcarrier, the number of bits corresponding to the modulation scheme and coding rate is transmitted per symbol. For example, when the modulation method is 16QAM (Quadrature Amplitude Modulation) and the coding rate is 1/2, 2 bits are transmitted per symbol.

  The transmission data is first subjected to convolutional coding processing as redundant coding for error correction, and then subjected to interleaving processing that makes it difficult for code errors to occur. Then, it is divided into 48 subcarriers and modulated. At this time, the data signal is assigned to each subcarrier with regularity.

The OFDM signal can be transmitted at high speed, but requires a wide frequency band, and may be considerably wide as 16.6 MHz in the IEEE 802.11a standard.
For this reason, in a propagation situation in which some specific subcarriers are affected by jamming radio waves, data communication may not be performed normally.

[Related technologies]
Incidentally, as a technology related to a wireless communication system using OFDM, there is Japanese Unexamined Patent Application Publication No. 2010-154417, “Wireless Communication System, Wireless Communication Method, and Wireless Transmission / Reception Device” (Hitachi Kokusai Electric Co., Ltd., Patent Document 1).

  Japanese Patent Laid-Open No. 2004-228688 estimates the channel condition of each subchannel based on received data, selects a subchannel to be used from among a plurality of subchannels based on the estimated channel condition, and selects the selected subchannel. Is transmitted to the other station.

JP 2010-154417 A

  However, the conventional wireless communication system has a problem that normal data communication cannot be performed when a specific subcarrier of OFDM is disturbed.

  The present invention has been made in view of the above circumstances, and when a specific subcarrier is disturbed, the communication quality is maintained by performing communication using only the unsubjected subcarrier. In addition, it is an object of the present invention to provide a communication system that can suppress the power consumption of terminals that are not communication targets, assuming that the communication time becomes longer by limiting the number of subcarriers.

  The present invention for solving the problems of the above-described conventional example is a wireless communication system that performs wireless communication between transmitting and receiving apparatuses using a plurality of subcarriers, where the transmitting and receiving apparatuses modulate transmission data and receive A baseband processing unit that demodulates the received signal and detects reception quality for each subcarrier included in the received signal, and determines a subcarrier to be used for transmission based on the received reception quality for each subcarrier In addition, the control unit that outputs the number of the used subcarriers, the modulation scheme and the coding rate at the time of transmission, and the channel usage period is obtained based on the modulation scheme, the coding rate, and the number of the used subcarriers at the time of transmission. The transmission / reception apparatus includes a communication processing unit that generates a transmission frame including the line usage period and outputs the transmission frame to the baseband processing unit.

  Further, in the communication system according to the present invention, when the communication processing unit of the transmission / reception apparatus receives a signal not addressed to itself, if the line use period included in the received signal is equal to or greater than a preset threshold value, It is characterized by shifting to the power saving mode.

  Further, according to the present invention, in the communication system, the communication processing unit of the transmission / reception device transmits the transmission data from the counterpart device based on the modulation scheme, the coding rate, and the number of used subcarriers at the time of transmission. The response signal waiting time is calculated, and when the response signal is not received within the calculated waiting time after transmission, the transmission data is retransmitted.

  According to the present invention, a wireless communication system that performs wireless communication between transmitting and receiving devices using a plurality of subcarriers, wherein the transmitting and receiving devices modulate transmission data, demodulate received signals, and receive signals A baseband processing unit that detects reception quality for each subcarrier included in the signal, and a used subcarrier to be used for transmission based on the detected reception quality for each subcarrier, and the number of the used subcarriers And a control unit that outputs a modulation scheme and a coding rate at the time of transmission, and a transmission frame that obtains a channel usage period based on the modulation scheme, the coding rate, and the number of used subcarriers at the time of transmission, and includes the channel usage period Since the communication system is a transmission / reception device that includes a communication processing unit that generates and outputs to the baseband processing unit, the communication quality due to subcarrier interference or the like In the case of deterioration, it is possible to maintain good communication quality by using only subcarriers whose quality is not deteriorated. Also, even if the number of subcarriers used decreases, a line usage period corresponding to that is obtained. Thus, there is an effect that a collision can be avoided by notifying surrounding transmitting / receiving devices.

  Further, according to the present invention, when the communication processing unit of the transmission / reception apparatus receives a signal that is not addressed to itself, and the line usage period included in the received signal is equal to or greater than a preset threshold value, the power saving mode Therefore, when the communication prohibition period is long, an unnecessary operation is not performed and power consumption can be reduced.

  Further, according to the present invention, the communication processing unit of the transmission / reception apparatus transmits a response signal transmitted from the partner apparatus to the transmission data based on the modulation scheme, the coding rate, and the number of used subcarriers at the time of transmission. If the response signal is not received within the calculated waiting time after transmission, the above communication system retransmits the transmission data, so the modulation scheme, coding rate, and subcarrier used An appropriate waiting time can be set according to the number, and the communication line can be used efficiently.

It is a schematic block diagram of the transmission / reception apparatus used in the radio | wireless communications system which concerns on this Embodiment. It is a block diagram of the configuration of the baseband unit 3 of the present apparatus. 3 is a configuration block diagram of a MAC processing unit 35. FIG. 4 is a schematic explanatory diagram of a second arithmetic processing unit 357 of the MAC processing unit 35. FIG. It is explanatory drawing which shows the QoS data frame format of IEEE802.11 specification. It is explanatory drawing which shows the QoS data frame format of this apparatus. FIG. 5 is a schematic explanatory diagram when a QoS data frame or the like is transmitted from a terminal A to a terminal B by a Stop & Wait method.

Embodiments of the present invention will be described with reference to the drawings.
[Outline of the embodiment]
The wireless communication system according to the embodiment of the present invention performs wireless communication between wireless transmission / reception apparatuses by the OFDM method, and the transmission-side wireless transmission / reception apparatus detects reception quality for each subcarrier from the received signal, Based on the received quality, a subcarrier having a good quality is determined as a used subcarrier, and a period for occupying a communication line is calculated based on the number of used subcarriers, a modulation scheme, and a coding rate, Generates transmission data to notify other stations of information indicating the occupation period, modulates it by the baseband processing unit, and wirelessly transmits it. When a specific subcarrier is disturbed, it receives the interference. It is possible to perform communication of good quality using only the subcarriers that are not present, and to notify other stations of the occupation period of the communication line according to the change in the number of used subcarriers. Becomes longer occupancy period the number of carriers is reduced is capable also prevent communication collisions.

  In addition, when the wireless transmission / reception apparatus receives a signal that is not addressed to itself, the wireless communication system according to the embodiment of the present invention is based on information indicating the occupation period of the communication line included in the received signal. Sets a transmission prohibition period during which no transmission is performed, and when the transmission prohibition period is equal to or greater than a preset threshold, the mode is shifted to the power saving mode, the number of used subcarriers is small, and the transmission prohibition period. If the device is long, it is possible to reduce power consumption by preventing unnecessary devices from performing unnecessary operations.

  Further, in the radio communication system according to the embodiment of the present invention, the radio transmission / reception apparatus on the transmission side further receives a response from the counterpart station based on the number of subcarriers used, the modulation scheme, and the coding rate. RSP timer time, which is the deadline to be used, is calculated and a response is awaited after the frame is transmitted, with the RSP timer time as an upper limit. An appropriate response waiting time can be set according to communication parameters, and the communication line can be efficiently It can be used.

[Configuration of transceiver device used in this system: FIG. 1]
A configuration of a transmission / reception apparatus (this apparatus) used in this system will be described with reference to FIG. FIG. 1 is a schematic configuration diagram of a transmission / reception apparatus used in the radio communication system according to the present embodiment.
As shown in FIG. 1, the transmission / reception device 2 used in this system includes a baseband unit 3, a radio unit (RF unit) 4, and an antenna 5. The baseband unit 3 and the RF unit 4 are The RF cable 4 and the antenna 5 are connected by an RF coaxial cable.

The baseband unit 3 is connected to the Ethernet (registered trademark) 1 and performs a conversion process between an Ethernet frame and a radio frame. Also, signal processing of baseband signals accompanying transmission / reception of radio signals is performed. The configuration and operation of the baseband unit 3 will be described later.
The RF unit 4 performs mutual conversion between a baseband signal and a radio signal, and transmits and receives the radio signal.
The antenna 5 emits a transmission signal as an electromagnetic wave into the space, and captures the electromagnetic wave in the space as a reception signal.

[Configuration of baseband unit 3: Fig. 2]
Next, the structure of the baseband part 3 of this apparatus is demonstrated using FIG. FIG. 2 is a configuration block diagram of the baseband unit 3 of the present apparatus.
As shown in FIG. 2, the baseband unit 3 includes a connector unit (RJ45) 31, an Ether PHY (Physical Layer) unit 32, a CPU 33, a local bus 34, and a MAC (Media Access Control). A control) processing unit 35, a baseband processing unit 36, a D / A conversion unit 37, and an A / D conversion unit 38.
The CPU 33 and the MAC processing unit 35 correspond to the control unit and the communication processing unit described in the claims, respectively.

The connector part 31 is a connector connected to Ethernet.
The Ether PHY unit 32 performs Ethernet physical layer processing and generates an Ethernet frame.

When the Ethernet frame is input, the CPU 33 disassembles the Ethernet frame and outputs it to the MAC processing unit 35 via the local bus 34 as wireless transmission data.
Further, the CPU 33 converts the data input from the MAC processing unit 35 according to the IP routing table and outputs the converted data to the Ether PHY unit 32.
Further, as a feature of the present apparatus, the CPU 33 sets a subcarrier to be used at the time of transmission based on the quality of the received signal, and notifies the MAC processing unit 35 of it. It is also possible to set the used subcarrier information set by the CPU 33 to the CPU 33 from the Ethernet via the connector unit 31.
Further, the CPU 33 notifies the MAC processing unit 35 of the modulation method and coding rate used at the time of transmission.

The MAC processing unit 35 includes wireless access control by CSMA / CA (Carrier Sense Multiple Access / Collision Avoidance), generation and analysis of a wireless MAC frame, control for the CPU 33, and baseband processing unit 36. Control and interface control for user data transmission and reception.
For example, the MAC processing unit 35 of the present apparatus performs generation of a wireless MAC frame or baseband processing in accordance with the setting or change of information on the used subcarrier from the CPU 33 while performing wireless access control. The transmission data amount for the unit 36 is adjusted (controlled), and information on the used subcarriers is notified.

  Further, as a feature of the present apparatus, the MAC processing unit 35 calculates a period (Duration value) for occupying a line in the communication based on the information on the number of subcarriers used, the modulation scheme, and the coding rate at the time of frame transmission. , Information to be notified to surrounding wireless transmitting / receiving devices is generated.

  As another feature, when the MAC processing unit 35 of this apparatus receives a radio signal not addressed to itself, it reads the Duration value included in the signal, and the line is occupied by the communication of the other party from the Duration value. A period (NAV (Network Allocation Vector) time; transmission stop period) during which transmission is prohibited is set, and if the NAV time is equal to or greater than a preset threshold value, control to shift to the sleeping mode is performed.

Furthermore, as another feature, the MAC processing unit 35 of the present apparatus waits for an ACK (ACKnowledgement; confirmation response) from the partner apparatus based on the number of subcarriers used and the modulation method during frame transmission (RSP timer time). Is calculated. The RSP timer time corresponds to the response signal waiting time described in the claims.
The configuration and operation of the MAC processing unit 35 will be described in detail later.

  The baseband processing unit 36 includes, as processing means for transmission, a header adding means, a convolutional coding processing means, an interleaving processing means, a subcarrier modulation means, and an IFFT (Inverse Fast Fourier Transform) process. Means, guard interval adding means, and symbol shaping means, and as receiving processing means, AFC (Automatic Frequency Control) processing means, guard interval removing means, and FFT (Fast Fourier Transform) processing Means, channel equalization means, subcarrier demodulation means, deinterleave processing means, Viterbi decoding processing means, and MAC frame generation means.

  At the time of transmission, the baseband processing unit 36 adds PLCP (Physical Layer Convergence Protocol) header information to the MAC frame input from the MAC processing unit 35, and performs convolutional coding, interleaving processing, subcarrier modulation, IFFT processing, Processing such as guard interval addition and symbol shaping is performed and output to the D / A converter 37.

  In addition, the baseband processing unit 36 performs AFC processing, guard interval removal, FFT processing, channel equalization (fading compensation), subcarrier demodulation, de-coding on the signal input from the A / D conversion unit 38 during reception. Interleave processing, Viterbi decoding processing, and the like are performed, and MAC frame data is generated and output to the MAC processing unit 35.

  As a feature of this apparatus, the baseband processing unit 36 receives the used subcarrier information from the MAC processing unit 35 at the time of transmission, and writes it in the header information of the PLCP header (or extended PLCP header). This notifies the receiving apparatus which subcarrier is used for transmission and the number of subcarriers used.

Furthermore, at the time of reception, the baseband processing unit 36 detects the reception signal quality (reception quality) of all received subcarriers, notifies the CPU 33 via the MAC processing unit 35, and is included in the PLCP header. The demodulating process is performed using the used subcarrier information, and the used subcarrier information is notified to the MAC processing unit 35. As the reception quality, for example, equalization error information (hereinafter referred to as “equalization error”) for each subcarrier detected by the channel equalization means can be considered.
Instead of the equalization error, for example, the baseband processing unit 36 may detect the reception signal level for all the subcarriers, and output the detected reception level information to the CPU 33 as the reception signal quality.

[Reception quality estimation]
The reception quality estimation in the baseband processing unit 36 will be described.
The channel equalization means of the baseband processing unit 36 performs propagation path compensation (equalization processing) and processing for detecting an equalization error for each subcarrier.
Then, the channel equalization means outputs the detected equalization error for each subcarrier to the CPU 33.

[Determination of subcarriers used]
The determination of the used subcarrier in the CPU 33 will be described.
The CPU 33 inputs the equalization error of each subcarrier calculated by the channel equalization means of the baseband processing unit 36, determines whether each subcarrier is disturbed based on the value, and transmits The subcarrier to be used for the determination is determined.
Specifically, the equalization error of each subcarrier is compared with a preset threshold value, and if it is larger than the threshold value, the subcarrier is not used as being disturbed, and the equalization error Subcarriers with a value less than or equal to the threshold value can be used as being not disturbed.

  Then, the CPU 33 determines whether or not all subcarriers are disturbed, determines a subcarrier to be used, and outputs the information to the MAC processing unit 35 as used subcarrier information. When the subcarrier to be used is determined, the number is also obtained.

[Configuration of MAC processing unit 35: FIG. 3]
Next, the configuration and operation of the MAC processing unit 35 will be described with reference to FIG. FIG. 3 is a configuration block diagram of the MAC processing unit 35.
As shown in FIG. 3, the MAC processing unit 35 includes a CPU I / F processing unit 351, an information storage unit 352, a MAC frame generation processing unit 353, a first arithmetic processing unit 354, and a wireless access control unit 355. A baseband I / F processing unit 356, a MAC frame analysis processing unit 358, and a control information transmission path 359. The baseband I / F processing unit 356 includes a second arithmetic processing unit 357.

The CPU I / F processing unit 351 is an interface unit connected to the CPU 33 illustrated in FIG.
The information storage unit 352 stores a modulation scheme, a coding rate, and information on used subcarriers (used subcarrier information) as transmission communication parameters set by the CPU 33. Further, the information storage unit 352 stores received signal modulation scheme, coding rate, and used subcarrier information read from the received signal as communication parameters at the time of reception. In addition to the information on which subcarrier is used, information indicating the number of subcarriers to be used may be stored as the used subcarrier information.

  The MAC frame generation processing unit 353 maps transmission data based on the used subcarrier information, the modulation scheme, and the coding rate from the radio access control unit 355, and performs QoS (Quality of Service) data frames and radio access. A control and management frame necessary for control is generated.

The first arithmetic processing unit 354 calculates a time parameter related to radio access control such as a duration value that is a line occupation time at the time of transmission and a NAV time.
In addition, as a feature of the present apparatus, the first arithmetic processing unit 354 calculates an RSP timer time that is an allowable time for waiting for an ACK based on the information on the used subcarrier, the modulation method, and the coding rate at the time of QoS frame transmission. To do.

The radio access control unit 355 performs radio access control by CSMA / CA.
In addition, as a feature of this apparatus, when the wireless access control unit 355 receives a signal not addressed to itself, the wireless access control unit 355 calculates the NAV calculated by the first arithmetic processing unit 354 based on the Duration value included in the received MAC frame. If the time is equal to or greater than a preset threshold value, the processing means in the MAC processing unit 35 is shifted to the sleep mode to perform control for suppressing power consumption.
If the number of subcarriers that can be used decreases due to interference, etc., it is assumed that the transmission time will be prolonged, and if it is not targeted for communication, unnecessary operations are suppressed to reduce power consumption. It is intended.
The sleep mode corresponds to the power saving mode described in the claims.

The baseband I / F processing unit 356 is an interface unit connected to the baseband processing unit 36 illustrated in FIG.
The second arithmetic processing unit 357 calculates the amount of bit data (number of data bits per symbol) to be transmitted to the baseband unit 36 during transmission. The operation of the second arithmetic processing unit 357 will be described later.

The MAC frame analysis processing unit 358 analyzes and disassembles the MAC frame received from the counterpart station and outputs the MAC frame to the wireless access control unit 355 and the CPU I / F processing unit 351.
The control information transmission path 359 is a transmission path for transmitting the communication control information from the baseband processing unit 36 shown in FIG. 2 and the equalization error as the reception quality to the CPU 33 shown in FIG.

[Operation of this apparatus: FIGS. 2 and 3]
Next, the operation of this apparatus will be described with reference to FIGS.
[Operations during transmission of QoS data frames (1)]
First, an operation when this apparatus transmits a QoS data frame or a management frame will be described.
First, the baseband processing unit 36 of this apparatus calculates an equalization error for each subcarrier based on, for example, CTS (Clear to Send) responded from the counterpart apparatus in response to RTS (Request to Send).

  Based on the equalization error received via the MAC processing unit 35, the CPU 33 determines which subcarriers cannot be used due to interference or the like, and performs MAC processing on the information on the subcarriers determined to be usable. To the unit 35. At the same time, the modulation scheme and coding rate used for transmission are output to the MAC processing unit 35 as communication parameters during transmission.

The MAC processing unit 35 stores information on the used subcarrier, which is a communication parameter at the time of transmission, a modulation scheme, and a coding rate in the information storage unit 352.
When user data is input to the CPU I / F processing unit 351 of the MAC processing unit 35, the MAC frame generation processing unit 353 generates a QoS data frame as a data frame.

  Although the structure of the QoS data frame will be described later, a Duration field for writing a Duration value that is a line occupation time is provided. The Duration value changes depending on the modulation method, coding rate, and number of subcarriers used.

[Calculation of Duration value]
Here, calculation of the Duration value which is a characteristic part of the present apparatus will be described.
In the case of transmitting QoS data or a management frame, the first arithmetic processing unit 354 of the present apparatus calculates a Duration value each time transmission is performed.
Specifically, the first arithmetic processing unit 354, based on an instruction from the wireless access control unit 355, transmits a modulation scheme, a coding rate, and a used subcarrier used by the wireless access control unit 355 read from the information storage unit 352. The Duration value is calculated based on the number and output to the wireless access control unit 355.

  As a method for obtaining the Duration value from the modulation scheme, coding rate, and number of subcarriers used, a correspondence table in which each parameter combination is associated with the Duration value is provided in advance, and the correspondence is based on the parameter combination set by the CPU 33. The Duration value to be read may be read, a calculation formula for obtaining the Duration value according to the combination of parameters is stored, the Duration value may be calculated based on the calculation formula, and the table and the calculation formula are It may be obtained in combination.

  Further, as a feature of this apparatus, the first arithmetic processing unit 352 calculates an RSP timer time which is a period for waiting for an ACK when transmitting QoS data or a management frame, which will be described later.

[Operation when sending QoS data frame etc. (2)]
Then, the wireless access control unit 355 outputs the Duration value to the MAC frame generation processing unit 353, and the MAC frame generation processing unit 353 writes the calculated Duration value in the Duration field of the MAC frame to generate a QoS data frame. . At that time, necessary information such as the MAC address of the device and the MAC address information of the other party is also received from the wireless access control unit 355 to generate a QoS data frame.
This makes it possible to notify the device that has received the QoS data frame of the line occupation period.
Further, the second arithmetic processing unit 357 of the MAC processing unit 35 calculates the number of data bits of one symbol length. The operation of the second arithmetic processing unit 357 will be described later.

  Then, the generated QoS frame is output to the baseband processing unit 36, and is transmitted after being subjected to subcarrier modulation, IFFT processing, guard interval insertion, and the like. At that time, the baseband processing unit 36 writes information on the used subcarriers in the PLCP header and transmits it. In this way, the operation at the time of transmission of a QoS data frame or the like in the present apparatus is performed.

[Operations when receiving QoS data frames, etc.]
Next, the operation of this apparatus when receiving a QoS data frame or a management frame will be described.
When receiving a QoS data frame or a management frame, the baseband processing unit 36 performs FFT processing, channel equalization, etc., and obtains an equalization error for each subcarrier (or obtains a received signal level for each subcarrier). In addition, demodulation is performed based on information on the used subcarriers included in the PLCP header, and demodulated data (MAC frame), equalization error (or reception level information), and information on used subcarriers are sent to the MAC processing unit 35. Is output.

Then, the MAC processing unit 35 outputs an equalization error (or reception level information) to the CPU 33, and the MAC frame analysis processing unit 358 analyzes the MAC frame, and wirelessly transmits the Duration value, destination information, and used subcarrier information. The data is output to the access control unit 355.
The radio access control unit 355 stores information on the used subcarriers input from the baseband processing unit 36, the modulation scheme at the time of reception, and the coding rate at the time of reception in the information storage unit 352. The information on the modulation scheme at the time of reception, the coding rate at the time of reception, and the used subcarrier at the time of reception is communication parameter information at the time of reception.

If the radio access control unit 355 determines from the input destination information that the received QoS data frame or the like is addressed to itself, the radio access control unit 355 instructs the first arithmetic processing unit 354 to calculate the Duration value in order to transmit ACK. .
The first arithmetic processing unit 354 calculates a Duration value based on information on subcarriers used during reception, which is a communication parameter during reception, a modulation scheme during reception, and a coding rate during reception. The calculated Duration value is output to the MAC frame generation processing unit 353 via the wireless access control unit 355.

The MAC frame generation processing unit 353 generates an ACK frame using the input Duration value.
Further, at the time of ACK transmission, the wireless access control unit 355 of the MAC processing unit 35 receives the number of subcarriers used at the time of reception stored in the information storage unit 352, the modulation scheme at the time of reception, and the coding rate at the time of reception. Are output to the second arithmetic processing unit 357, and the second arithmetic processing unit 357 calculates the number of data bits of one symbol length and outputs the number of data bits to the baseband processing unit 36. The operation of the second arithmetic processing unit 357 will be described later.

  On the other hand, the CPU 33 performs a process of determining a used subcarrier based on the equalization error (or reception level information) of each input subcarrier, and information of the MAC processing unit 35 as information of the used subcarrier at the time of transmission. Store in the storage unit 352. This is used when the self transmits a QoS data frame or the like.

  If the received QoS data frame or the like is not addressed to itself, the wireless accessibility control unit 355 performs control to shift to the sleep mode according to the NAV time set based on the received Duration value. However, this process will be described later.

[Operation of Second Arithmetic Processing Unit 357: FIG. 4]
Next, the configuration and operation of the second arithmetic processing unit 357 will be described with reference to FIG. FIG. 4 is a schematic explanatory diagram of the second arithmetic processing unit 357 of the MAC processing unit 35.
The second arithmetic processing unit 357 calculates the number of data bits of one symbol length of the transmission frame. As shown in FIG. 4, the number of used used subcarriers, the modulation scheme, the coding rate, and the like. Based on the above, the number of data bits of one symbol length is calculated.

  As shown in FIG. 4, parameters necessary for calculation are input from the selection means 71, 72, 73 to the second calculation processing unit 357. Each selection means 71, 72, 73 is provided in the wireless access control unit 355.

  The selection unit 71 outputs either the number of used subcarriers at the time of transmission or the number of used subcarriers at the time of reception to the second arithmetic processing unit 357, and the selection unit 72 selects the modulation scheme or reception at the time of transmission. Any one of the time modulation schemes is output to the second arithmetic processing unit 357, and the selection means 73 selects either the encoding rate at the time of transmission or the encoding rate at the time of reception from the second arithmetic processing unit. 357.

These parameters are stored in the information storage unit 352 as communication parameters at the time of transmission / communication parameters at the time of reception, and the selection means 71, 72, and 73 can communicate at the time of transmission if a QoS data frame or the like is transmitted. When a parameter is selected and the Ack frame is transmitted, a communication parameter at the time of reception (a parameter specified from the transmission side) is selected.
Then, based on the selected number of used subcarriers, modulation scheme, and coding rate, second arithmetic processing unit 357 calculates the number of data bits of one symbol length of the transmission frame, and outputs it to baseband processing unit 36. .
In this way, the operation of the second arithmetic processing unit 357 is performed.

[QoS data frame: FIG. 5]
Next, the format of the QoS data frame will be described with reference to FIG. FIG. 5 is an explanatory diagram showing a QoS data frame format of the IEEE 802.11 standard.
As shown in FIG. 5, the QoS frame format is composed of an IP packet (data) and FCS following a MAC header including frame control, Duration, and the like. The Duration field is 2 bytes.

[QoS data frame of this device: FIG. 6]
Next, the QoS data frame format of this apparatus will be described with reference to FIG. FIG. 6 is an explanatory diagram showing the QoS data frame format of the present apparatus.
As shown in FIG. 6, the Duration field is set to 4 bytes in the QoS data frame format of the present apparatus. In this case, by limiting the number of subcarriers used, the Duration value can be written even if the line occupation period becomes longer.

[Calculation of RSP timer time: FIG. 7]
Next, calculation of the RSP timer time, which is a feature of the present apparatus, will be described with reference to FIGS. FIG. 7 is a schematic explanatory diagram when a QoS data frame or the like is transmitted from the terminal A to the terminal B by the Stop & Wait method.
The first arithmetic processing unit 352 of the MAC processing unit 35 calculates an RSP timer time that is an allowable period for waiting for an ACK when transmitting QoS data or a management frame. In the example of FIG. 7, the first arithmetic processing unit 352 of the terminal A performs processing for calculating the RSP timer time.

First, the basic operation will be described with reference to FIG.
In this communication system, communication is performed by an ARQ (Auto ReQuest) method, and as shown in FIG. 7, the terminal A on the transmission side times out the RSP timer time after transmitting a QoS data frame or the like. Until the ACK is received, if the ACK is not received within the RSP timer time, processing such as data retransmission is performed.

When the terminal B receives the QoS data frame or the like from the terminal A and determines that it is addressed to itself, the terminal B transmits ACK after the SIFS period.
Further, when the terminal C that is not the communication target receives the QoS data frame or the like from the terminal A, the NAV time (transmission prohibited period) is set based on the Duration value included in the QoS data frame, and transmission is not performed during this period. .

  The time required from when terminal A transmits a QoS data frame or the like until it receives ACK from terminal B varies depending on the modulation scheme, coding rate, and number of subcarriers used. For example, if the number of subcarriers used is small and the modulation method is BPSK, the response time is long, and if the number of subcarriers is large and the modulation method is 16QAM, the response time is short. The parameters used here are communication parameters at the time of transmission stored in the information storage unit 352.

  The first arithmetic processing unit 352 that determines the RSP timer time provides a correspondence table in advance that associates the combination of each parameter (modulation method, coding rate, and number of subcarriers used) with the RSP timer time, and is set by the CPU 33. The corresponding RSP timer time may be read based on the combination of the parameters, or a calculation formula for calculating the RSP timer time according to the parameter is stored, and the RSP timer time is calculated based on the calculation formula. May be. Further, a table and a calculation formula may be combined.

The wireless access control unit 355 of this apparatus waits for an ACK from the terminal B with the RSP timer time calculated by the first arithmetic processing unit 352 as a deadline after sending out the QoS data frame or the like, and within the RPS timer time If ACK is not received, retransmission by ARQ (Automatic Repeat reQuest) communication is performed.
As described above, in this apparatus, by setting the RSP timer time according to the number of subcarriers used at the time of transmission, the modulation method, and the coding rate and waiting for ACK, it is possible to obtain an appropriate RSP timer time. The line can be used efficiently.

[sleep mode]
Next, the transition to the sleep mode, which is a feature of this apparatus, will be described with reference to FIGS.
If the received QoS data frame or the like is not addressed to itself, the wireless access control unit 355 of the MAC processing unit 35 sets the NAV time based on the Duration value in the received signal.

Here, if the set NAV time is equal to or greater than the threshold, the wireless access control unit 355 of the present apparatus shifts each processing unit of the MAC processing unit 35 to the sleep mode.
Specifically, the wireless access control unit 355 of this apparatus calculates the NAV time that is its own transmission prohibition period based on the received Duration value, and compares the NAV time with a preset threshold value. When the NAV time is equal to or greater than the threshold, the CPU I / F processing unit 351, the first arithmetic processing unit 352, the MAC frame generation processing unit 353, the baseband I / F processing unit 356, the second arithmetic processing The unit 357 and the MAC frame analysis processing unit 358 are shifted to the sleep mode.

Here, the NAV time set based on the received Duration value is compared with the threshold value, but it is determined whether or not to shift to the sleep mode using the Duration value itself described in the received MAC frame. It may be.
That is, when the received Duration value is greater than or equal to another preset threshold value, the wireless access control unit 355 shifts each processing unit of the MAC processing unit 35 to the sleep mode.

As a result, if there are subcarriers that cannot be used due to interference or the like, this device must perform communication with a small number of subcarriers. It is possible to suppress unnecessary operation in a device that is not present and to reduce power consumption.
When the mode is shifted to the sleep mode, the sleep mode is maintained at least until the NAV time elapses. Thereafter, when a reception or transmission event occurs, the mode is returned from the sleep mode to a mode in which the normal operation is performed. Such a control can be considered.

[Effect of the embodiment]
According to the radio transmission / reception apparatus and the radio communication system using the same according to the embodiment of the present invention, the baseband processing unit 36 detects equalization errors as reception quality for all subcarriers of the received signal, and the CPU 33 , Comparing the preset threshold value with the equalization error of each subcarrier, and if the equalization error is less than the threshold value, it is determined as a subcarrier that can be used at the time of transmission as not being disturbed, and at the time of transmission Information on the subcarriers used, the modulation scheme at the time of transmission, and the coding rate at the time of transmission are output as communication parameters to the MAC processing unit 35, and the MAC processing unit 35 occupies the communication line based on the communication parameters. The duration value, which is a period, is calculated, a QoS data frame including the duration value is generated, modulated by the baseband processing unit 36, and wirelessly transmitted Therefore, if the quality of the transmission path deteriorates due to interference of a specific subcarrier, good quality communication can be performed using subcarriers that are not disturbed, and There is an effect that the communication line occupation period according to the number of carriers can be notified to other wireless transmission / reception devices to prevent a communication collision.

  Further, according to the wireless transmission / reception apparatus and the wireless communication system according to the present embodiment, when the MAC processing unit 35 receives a QoS data frame that is not addressed to itself, the MAC processing unit 35 determines from the Duration value included in the received signal that If a NAV time during which transmission is not performed is set and the NAV time is equal to or greater than a preset threshold, the processing unit of the MAC processing unit 35 is a wireless transmission / reception device that shifts to the sleep mode, and therefore transmission is prohibited. When the period is long, there is an effect that power consumption can be reduced by preventing unnecessary operations from being performed in a device that is not a communication target.

  Furthermore, according to the radio transmission / reception apparatus and radio communication system according to the present embodiment, when transmitting a QoS data frame or the like, the MAC processing unit 35 uses the number of subcarriers used during transmission and the modulation scheme used during transmission. And an RSP timer time that is a time limit for receiving an ACK from the counterpart station based on the coding rate at the time of transmission, and after transmitting the QoS data frame, a wireless transmission / reception apparatus that waits for a response with the RSP timer time as an upper limit Therefore, an appropriate standby time can be set according to the number of subcarriers used, the modulation method, and the coding rate, and there is an effect that the communication line can be used efficiently.

  INDUSTRIAL APPLICABILITY The present invention is suitable for a wireless communication system that can perform stable communication according to propagation path conditions and can reduce power consumption of a wireless transmission / reception apparatus.

  1 ... Ethernet, 2 ... Transceiver, 3 ... Baseband part, 4 ... Radio part (RF part), 5 ... Aerial, 31 ... Connector part, 32 ... Ether PHY section, 33 ... CPU, 34 ... local bus, 35 ... MAC processing section, 36 ... baseband processing section, 37 ... D / A conversion section, 38 ... A / D Conversion unit, 351 ... CPU I / F processing unit, 352 ... information storage unit, 353 ... MAC frame generation processing unit, 354 ... first arithmetic processing unit, 355 ... radio access control , 356... Baseband I / F processing unit, 357... Second arithmetic processing unit, 358... MAC frame analysis processing unit, 359... Control information transmission path, 71, 72, 73. ..Selection means

Claims (3)

A wireless communication system that performs wireless communication between transmitting and receiving apparatuses using a plurality of subcarriers,
The transmission / reception device modulates transmission data, demodulates the received signal, and detects a reception quality for each subcarrier included in the received signal; and
Based on the detected reception quality for each subcarrier, the control unit that determines the number of subcarriers to be used for transmission and outputs the number of subcarriers to be used, the modulation scheme and the coding rate at the time of transmission,
Communication for obtaining a channel usage period based on the modulation scheme, the coding rate, and the number of used subcarriers at the time of transmission, generating a transmission frame including the channel usage period, and outputting the transmission frame to the baseband processing unit A wireless communication system, characterized in that the wireless communication system includes a processing unit.   When the communication processing unit of the transmission / reception device receives a signal that is not addressed to itself, the communication processing unit shifts to a power saving mode if the line usage period included in the received signal is equal to or greater than a preset threshold value. The wireless communication system according to claim 1.   The communication processing unit of the transmission / reception device calculates the waiting time of the response signal transmitted from the counterpart device for the transmission data based on the modulation scheme, the coding rate, and the number of used subcarriers during transmission, 3. The wireless communication system according to claim 1, wherein after transmission, when the response signal is not received within the calculated waiting time, the transmission data is retransmitted. 4.

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