JP4861637B2 - Wireless LAN system - Google Patents

Description

  The present invention relates to a wireless LAN system that transmits a signal that occupies a wireless medium.

  Conventionally, in addition to a wireless LAN system compliant with the IEEE 802.11b standard (hereinafter abbreviated as “11b”) having a transmission rate of 11 Mbit / s, IEEE 802.11a having a maximum transmission rate of 54 Mbit / s ( Hereinafter, abbreviated as “11a”.) A wireless LAN system compliant with the standard has been proposed. Further, IEEE802.11g (hereinafter abbreviated as “11g”) having a feature obtained by adding IEEE802.11b and IEEE802.11a has been proposed. Hereinafter, in the wireless LAN system based on these standards, both the access point and the station are referred to as “legacy terminal”, the legacy access point is referred to as “legacy AP”, and the legacy station is referred to as “legacy STA”.

  In recent years, a high speed of 100 Mbit / s class is required in a wireless LAN. As one of the achievement techniques, a technique for improving the transmission speed by using a frequency band n times (n is a natural number) that of legacy terminals has been proposed. Hereinafter, both an access point and a station in a wireless LAN system that performs such high-speed transmission are referred to as “HT (High Throughput) terminal”, an HT access point as “HTAP”, and an HT station as “HTSTA”. In FIG. 40, the HT terminal includes the frequency band f1 used by the legacy terminal, and uses, for example, the frequency band fh having a bandwidth three times that of the legacy terminal. Currently, the HT terminal and the legacy terminal communicate with each other using the same frequency band, that is, coexistence of different wireless LAN systems is being studied.

  Conventionally, as an example in which different wireless LAN systems coexist using the same frequency band, there is coexistence of the 11b system and the 11g system. This wireless LAN system adopts a configuration as shown in FIG. That is, the 11g access point 100 controls both the 11g station 101 and the 11b station 102.

  In the case of such a configuration, as illustrated in FIG. 42, the 11g station 101 can perform high-speed transmission by transmitting a data frame using a modulation scheme based on OFDM (Orthogonal Frequency Division Multiplexing). However, the station 102 of 11b recognizes it as an interference signal from another system because the OFDM signal is not the signal of 11b. Depending on the signal level, the station 102 of 11b may transmit the data frame by a modulation method based on CCK (Complementary Code Keying). In such a case, packet collision occurs and throughput is reduced.

  Therefore, as shown in FIG. 43, the 11g station 101 can demodulate at the station 102 of 11b and the IEEE 802.11 (not shown) (hereinafter abbreviated as “11”) before transmitting the OFDM signal. A CTS (Clear To Send: signal notifying completion of reception) is transmitted by a modulation method based on DSSS (Direct Sequence Spread Spectrum). Accordingly, NAV (Network Allocation Vector: transmission suppression by virtual carrier sense) is set for the station 102 of 11b and the 11 station (not shown) to avoid collision.

  Here, the CTS frame format employs the configuration shown in FIG. That is, the frame control unit 103 as a MAC (Media Access Control) header, a duration unit 104, a receiver address 105, and an FCS (Frame Check Sequence) unit 106 are configured. Other terminals that have received such a CTS set NAV in the section described in the duration unit 104 to suppress transmission. Thereby, a collision is avoided.

Also, even when the 11b station 102 is transmitting first, the 11g station 101 can demodulate or recognize the transmission signal of the 11b station 102, and thus collision can be avoided. That is, as shown in FIG. 45, the 11g station 101 demodulates (or recognizes) the data frame (CCK) transmitted from the 11b station 102, sets a back-off so that no collision occurs, and then An OFDM signal is transmitted.
Satoshi Hori and four others, “Examination of high-speed wireless LAN based on system capacity”, 2002 IEICE General Conference B-5-250 Hideaki Matsue and 1 other, "802.11 High-Speed Wireless LAN Textbook", IDG Japan, 2003 IEEE Std 802.11g-2003

  Here, when the HTAP communicates with the HTSTA, as shown in FIG. 46, a beacon (HT beacon), a control frame (HT control frame), and a data frame (HT data) are transmitted as a notification signal transmitted at regular intervals. It is conceivable that all frames) are transmitted using HT transmission, that is, using a frequency band wider than that of the legacy terminal, thereby realizing high-speed transmission. Hereinafter, a series of procedures shown in FIG. 46 is referred to as an “HT sequence”. In addition, the downward arrow in the figure indicates transmission / reception of a signal from HTAP to HTSTA, and the upward arrow indicates transmission / reception of a signal from HTSTA to HTAP. “HT ACK” indicates a signal for confirming completion of reception for “HT control frame” or “HT DATA frame”.

  However, as shown in FIG. 47, when the HT terminals 110 to 112 and the legacy terminals 113 and 114 perform communication in the same frequency band, they can recognize transmission signals from other terminals. Can not. For this reason, the HT terminals 110 to 112 and the legacy terminals 113 and 114 recognize transmission signals from other terminals as interference signals from other systems, and packet collisions frequently occur. As a result, the throughput decreases. That is, there is a problem that the communication speed between the legacy terminals and between the HT terminals is significantly reduced.

  The present invention has been made in view of such circumstances, and an object thereof is to provide a high-speed wireless LAN system capable of avoiding packet collision and maintaining an original transmission rate.

  (1) In order to achieve the above object, the present invention has taken the following measures. That is, the transmitter according to the present invention is a transmitter applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system. An occupancy that generates an occupancy signal that is compatible with the first radio communication system and notifies the first radio communication system that the second radio communication system occupies a radio medium. A signal generation unit; and a transmission unit that performs communication in the second wireless communication system after transmitting the occupied signal using all frequencies in the second frequency band.

  As described above, since the occupied signal is compatible with the first wireless communication system, the first wireless communication system can recognize the occupied signal and notify that the second wireless communication system is occupied. it can. Further, since the communication in the second wireless communication system is performed after transmitting the occupied signal using all frequencies in the second frequency band, the wireless medium is controlled by suppressing the transmission to the first wireless communication system. Communication of the second wireless communication system can be performed. Thereby, collision of packets can be avoided and a reduction in throughput can be prevented. As a result, communication can be performed at the original transmission rate in the second wireless communication system.

  (2) In the transmitter according to the present invention, the occupancy signal generator adds information specifying a period during which the second radio communication system completely occupies a radio medium to the occupancy signal. The transmitting unit occupies a wireless medium within the period and performs communication in the second wireless communication system.

  Thus, since the period during which the second wireless communication system completely occupies the wireless medium is designated, it is possible to prevent the first wireless communication system from transmitting information within that period. Thereby, collision of packets can be avoided and a reduction in throughput can be prevented. As a result, communication can be performed at the original transmission rate in the second wireless communication system.

  (3) Moreover, in the transmitter according to the present invention, the occupancy signal generation unit adds, to the occupancy signal, information that the second radio communication system occupies a part of a period of a radio medium, The transmitting unit occupies a wireless medium within the partial period based on the information and performs communication in the second wireless communication system.

  Thus, by occupying a part of the period of the wireless medium, it is possible to ensure a period during which the first wireless communication system performs communication in the other part. Therefore, while the second wireless communication system occupies the wireless medium, transmission suppression is performed in the first wireless communication system, packet collision is avoided, and a decrease in throughput in the second wireless communication system is prevented. . On the other hand, while the second wireless communication system does not occupy the wireless medium, the first wireless communication system can perform communication, so that the first and second wireless communication systems can coexist.

  (4) Further, in the transmitter according to the present invention, the second frequency band has a bandwidth that is n times (n is a natural number) the first frequency band.

  As described above, since the bandwidth of the frequency used in the second radio communication system is n times (n is a natural number) of the first frequency band, the transmission speed is improved as compared with the first radio communication system. Is possible.

  (5) Further, in the transmitter according to the present invention, the occupied signal generation unit includes a symbol repetition unit that repeatedly outputs transmission data corresponding to the occupied signal n times (n is a natural number) in a predetermined symbol unit. It is characterized by.

  In this way, transmission data corresponding to the occupied signal is repeatedly output n times (n is a natural number) in a predetermined symbol unit. Therefore, by converting this output signal from a frequency signal to a time signal, Signals stacked along the frequency axis can be transmitted. That is, in the second wireless communication system, a frequency band having a bandwidth n times that of the frequency band used in the first wireless communication system is used, so that the occupation is compatible with the first wireless communication system. By repeating the signal n times, the occupied signal can be transmitted in all frequencies of the frequency band used by the second wireless communication system. As a result, the first wireless communication system can be surely recognized that the wireless medium has been occupied, and transmission can be reliably suppressed. As a result, collision of packets can be avoided, a reduction in throughput can be prevented, and communication can be performed at the original transmission rate in the second wireless communication system.

  (6) Moreover, in the transmitter which concerns on this invention, the said occupation signal generation part transmits the said occupation signal intermittently, It is characterized by the above-mentioned.

  As described above, since the occupancy signal is transmitted intermittently, when transmitting the occupancy signal, the wireless medium is occupied in the second wireless communication system, the transmission is suppressed in the first wireless communication system, and packet collision occurs. Is avoided, and a decrease in throughput in the second wireless communication system is prevented. On the other hand, when the occupancy signal is not transmitted, the wireless medium is not occupied by the second wireless communication system, so that communication can be performed by the first wireless communication system. As a result, the first and second wireless communication systems can coexist. Here, “intermittent” means that the occupation signal is not transmitted at a certain time interval. For example, the notification signal is transmitted three times within a predetermined time. Among them, the occupancy signal is transmitted twice together for the first two notification signals, and the occupancy signal is not transmitted for the last notification signal. In addition, the occupation signal may be transmitted twice together with the remaining two notification signals without transmitting the occupation signal for the first notification signal.

  (7) Further, in the transmitter according to the present invention, the transmission unit communicates with a start signal for notifying that a period for performing communication in the second radio communication system starts or in the second radio communication system. Among the end signals for notifying that the period for performing is completed, at least the start signal is transmitted.

  As described above, since at least the start signal is transmitted, the receiver of the second wireless communication system can clearly grasp that the communication period has started. Further, by transmitting the end signal, the receiver of the second wireless communication system can clearly grasp that the period of communication has ended without measuring the time from the start. Since the reception side clearly understands the start and end of the period, it is possible to facilitate the configuration of the system in which the second wireless communication system changes the occupation period in which a part of the period of the wireless medium is occupied. The first and second wireless communication systems can coexist.

  (8) Further, in the transmitter according to the present invention, the occupying signal generation unit adds identification information for recognizing the occupying signal to the occupying signal in the second radio communication system. .

  As described above, since the identification information for recognizing the occupied signal in the second wireless communication system is added to the occupied signal, the occupied signal notifies the first wireless communication system that the wireless medium is occupied. Therefore, it can be recognized by the receiver of the second wireless communication system. Accordingly, the receiver of the second wireless communication system can determine whether the data transmitted after the occupation signal is transmitted to the second wireless communication system. As a result of the determination, if the data transmitted after the occupation signal is transmitted to the second wireless communication system, the data is demodulated, while the data transmitted after the occupation signal is the first. If it is not transmitted to the wireless communication system 2, the reception operation is stopped. As a result, unnecessary operations can be avoided and power consumption can be saved.

  (9) Moreover, in the transmitter according to the present invention, the occupying signal generation unit converts the center frequency of the input signal into a predetermined frequency, and outputs at least one frequency conversion unit; And an addition unit that adds the input signal and the signal output from the frequency conversion unit.

  In this way, since the center frequency of the input signal is converted to a predetermined frequency and the input signal is added, a plurality of radio signals arranged in a frequency direction can be generated when viewed in the frequency direction. Thereby, it is possible to notify that the second radio communication system occupies each frequency band used by the first radio communication system.

  (10) The receiver according to the present invention is applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system. A decimation circuit that cuts out and outputs 1 / n of the occupied signal received from the transmitter according to claim 3, and outputs a reception data by demodulating a signal input from the decimation circuit And a demodulator.

  Thus, since 1 / n of the received occupancy signal is cut out and output, one occupancy signal can be obtained from the occupancy signal repeated n times by the symbol repetition circuit in the transmitter. As a result, the minimum necessary occupied signal can be demodulated.

  (11) The receiver according to the present invention is applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system. A start determination unit that determines a start of a period in which the second wireless communication system occupies a wireless medium based on the start signal received from the transmitter according to claim 7, and the period is A measurement unit that measures a time elapsed from the start, an end determination unit that determines the end of the period based on the time elapsed from the start of the period and the start signal, and a determination of the start and end of the period And a control unit that outputs a signal for notifying the result.

  As described above, based on the start signal, the second wireless communication system recognizes the start of the period in which the wireless medium is occupied, measures the time elapsed after the start of the period, and elapses from the start of the period. Since the end of the period is recognized based on the time and a broadcast signal transmitted at regular intervals in the second wireless communication system, it is ensured that the second wireless communication system occupies the wireless medium on the receiving side. It becomes possible to grasp. Since the reception side clearly understands the start and end of the period, it is possible to facilitate the configuration of the system in which the second wireless communication system changes the occupation period in which a part of the period of the wireless medium is occupied. The first and second wireless communication systems can coexist.

  (12) The receiver according to the present invention is applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system. A start determination unit that is a receiver and determines the start of a period in which the second wireless communication system occupies a wireless medium based on the start signal received from the transmitter according to claim 7, and claim 7. An end determination unit that determines the end of the period based on the end signal received from the transmitter described above, and a control unit that outputs a signal for notifying the determination result of the start and end of the period It is characterized by that.

  As described above, the reception side can surely grasp the start and end of the period in which the second wireless communication system occupies the wireless medium by the start signal and the end signal. Since the reception side clearly understands the start and end of the period, it is possible to facilitate the configuration of the system in which the second wireless communication system changes the occupation period in which a part of the period of the wireless medium is occupied. The first and second wireless communication systems can coexist.

  (13) The receiver according to the present invention is applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system. 9. A receiver that recognizes the identification information based on the occupied signal received from the transmitter according to claim 8, and, when the identification information is recognized, demodulates the received signal and receives it. A receiving unit that outputs data and stops the receiving operation when the identification information is not recognized.

  As described above, since the identification information is recognized, it is possible to determine whether the data transmitted after the occupation signal is transmitted to the second wireless communication system. That is, when the identification information is recognized, it can be determined that the signal transmitted after the occupied signal is transmitted to the second wireless communication system, and thus the signal is demodulated. On the other hand, when the identification information is not recognized, it can be determined that the signal data transmitted after the occupation signal is not transmitted to the second wireless communication system, and the reception operation is stopped. As a result, unnecessary operations can be avoided and power consumption can be saved.

  (14) Further, an access point according to the present invention includes any one of the transmitters described above.

  Thereby, collision of packets can be avoided and a reduction in throughput can be prevented.

  (15) A station according to the present invention includes at least one of the receivers.

  As a result, since the start and end of the above period are clearly grasped on the receiving side, the system configuration for changing the occupation period in which the second radio communication system occupies a part of the period of the radio medium is facilitated. The first and second wireless communication systems can coexist.

  (16) Further, the wireless LAN system according to the present invention is characterized by comprising the above access point and the above station.

  Thereby, collision of packets can be avoided and a reduction in throughput can be prevented. In addition, the first and second wireless communication systems can coexist.

  According to the present invention, since the occupied signal is compatible with the first wireless communication system, the first wireless communication system is made to recognize the occupied signal and notify that the second wireless communication system is occupied. be able to. Further, since the communication in the second wireless communication system is performed after transmitting the occupied signal using all frequencies in the second frequency band, the wireless medium is controlled by suppressing the transmission to the first wireless communication system. Communication of the second wireless communication system can be performed. Thereby, collision of packets can be avoided and a reduction in throughput can be prevented. As a result, communication can be performed at the original transmission rate in the second wireless communication system.

  In the wireless LAN system according to the present invention, the HT terminal uses a frequency band n times (n is a natural number) that of the legacy terminal. In the example shown in FIG. 40, the HT terminal uses a frequency band whose bandwidth is three times that of the legacy terminal. Thereby, high-speed transmission is realized between HT terminals.

  In addition, HTAP is compatible with legacy terminals in all frequencies (all bands) communicating with HTSTA, and notifies that legacy terminals will occupy the wireless medium in a format that can be demodulated (eg, CTS). An occupancy signal is transmitted. As a result, the HTAP logically occupies time for performing the HT sequence with respect to the legacy terminal. The notification signal means a beacon, and the occupation signal means CTS. Further, as will be described later, it is also possible to use CF-poll or MAC frame as the occupied signal instead of CTS.

(First embodiment)
FIG. 1 is a block diagram showing a configuration of an HTSTA transmitter applied to the wireless LAN system according to the first embodiment, and FIG. 2 is a configuration of a legacy STA transmitter applied to the legacy wireless LAN system. FIG. In FIG. 1, in an HTSTA transmitter 1, transmission data is input to a MAC circuit 2, and a frame transmission / reception method, a frame format, and the like serving as a data transmission / reception unit are defined. The error correction encoder 3 performs error correction encoding on the signal input from the MAC circuit 2. The modulator 4 performs modulation such as BPSK (Binary PSK) and QPSK (Quadrature PSK) on the signal input from the error correction encoder 3. The IFFT circuit 5 converts the signal input from the modulator 4 from a frequency signal to a time signal. The filter circuit 6 passes and outputs only a signal in a desired band among the signals input from the IFFT circuit 5, and the output signal is transmitted by the antenna 7. The error correction encoder 3, the modulator 4, the IFFT circuit 5, and the filter circuit 6 constitute a transmission circuit 1a.

  As shown in FIG. 2, in the legacy STA transmitter 10, the MAC circuit 11, the error correction encoder 12, the modulator 13, the IFFT circuit 14, the filter circuit 15, and the antenna 16 are also included in the HTSTA transmitter 1. Performs almost the same function. The error correction encoder 12, modulator 13, IFFT circuit 14, and filter circuit 15 constitute a transmission circuit 10a.

  However, the IFFT circuit 5 in the transmitter 1 of the HTSTA uses an IFFT circuit having the number of points n times (here, for example, n = 3) as compared with the IFFT circuit 14 in the transmitter 10 of the legacy STA. ing. The filter circuit 6 in the transmitter 1 of the HTSTA is a filter circuit having a pass bandwidth that is n times (here, for example, n = 3) as compared with the filter circuit 15 in the transmitter 10 of the legacy STA. I use it. As a result, HTSTA enables high-speed transmission using n times the bandwidth compared to legacy STA.

  FIG. 3 is a block diagram showing a configuration of an HTAP transmitter applied to the wireless LAN system according to the first embodiment. In the HTAP transmitter 20, the MAC circuit 21 is controlled by the control circuit 21 a to define a frame transmission / reception method, a frame format, and the like for transmission data. The error correction encoder 22 performs error correction encoding on the signal input from the MAC circuit 21. The modulator 23 performs modulation such as BPSK (Binary PSK) or QPSK (Quadrature PSK) on the signal input from the error correction encoder 22. Under the control of the control circuit 21a, the switch 24 switches the signal input from the modulator 23 to the symbol repetition circuit 25 or the IFFT circuit 26 and outputs it.

  The symbol repetition circuit 25 repeats n times (n is a natural number) of a predetermined symbol unit, which is obtained by performing error correction coding and modulation processing on transmission signal data corresponding to the occupied signal generated by the MAC circuit 21 and outputs the result. Specifically, the symbol is repeated n times for the signal input from the switch 24 and output to the IFFT circuit 26. As shown in FIG. 4, the symbol repetition circuit 25 is a circuit that repeats an input signal n times in OFDM symbol units (here, for example, n = 3 is shown).

  The IFFT circuit 26 converts the signal input from the switch 24 or the symbol repetition circuit 25 from a frequency signal to a time signal. The filter circuit 27 passes and outputs only a signal of a desired band among the output signals of the IFFT circuit 26, and the output signal is transmitted by the antenna 28. The error correction encoder 22, modulator 23, switch 24, symbol repetition circuit 25, IFFT circuit 26, and filter circuit 27 constitute a transmission circuit 20a.

  When the output from the modulator 23 is directly output to the IFFT circuit 26 by the switch 24, the transmitter 20 of this HTAP transmits an HT signal using a bandwidth n times that of the legacy terminal as shown in FIG. Can be performed. Further, when the output from the modulator 23 is output to the IFFT circuit 26 via the symbol repetition circuit 25 by the switch 24, three identical legacy signals are stacked along the frequency axis as shown in FIG. It is possible to transmit a signal of the shape.

  In the above description, the symbol repetition circuit 25 is arranged between the modulator 23 and the IFFT circuit 26. However, the present invention is not limited to this. Other configurations may be adopted as long as the functions equivalent to this configuration are achieved.

  Further, in the following description, a portion including the transmission circuit 20a, the MAC circuit 21, and the control circuit 21a excluding the symbol repetition circuit 25 in FIG. Further, a portion including the transmission circuit 20 a including the symbol repetition circuit 25, the MAC circuit 21, and the control circuit 21 a is defined as an occupied signal generation unit 301. That is, the control circuit 21a included in the occupation signal generation unit 301 instructs transmission of the legacy signal, and the transmission signal data is output from the MAC circuit 21 to the transmission circuit 20a, thereby transmitting a signal compatible with the legacy terminal. Then, the control circuit 21a included in the transmission unit 300 instructs transmission of the HT signal, and the transmission signal data is output from the MAC circuit 21 to the transmission circuit 20a, thereby transmitting a signal compatible with the HT terminal. And

  FIG. 7 is a block diagram showing a configuration of an HTSTA receiver applied to the wireless LAN system according to the first embodiment. Here, a case will be described in which the present invention is applied to a wireless LAN system including an HT beacon during the HT sequence. That is, in the case of a wireless LAN system including an HT beacon in the HT sequence, only the HT signal needs to be demodulated. As shown in FIG. 7, in the HTSTA receiver 30, the radio signal received by the antenna 31 is processed by the filter circuit 32 to pass only a signal in a desired band. The output signal of the filter circuit 32 is converted from a time signal to a frequency signal by the FFT circuit 33. The demodulator 34 converts the signal input from the FFT circuit 33 into a bit string based on the signal point. The error correction decoder 35 performs error correction decoding on the signal input from the demodulator 34. The MAC circuit 36 reads out a frame transmission / reception method, a frame format, and the like based on a signal input from the error correction decoder 35, and outputs received data. The filter circuit 32, the FFT circuit 33, the demodulator 34, and the error correction decoder 35 constitute a receiving circuit 30a.

  On the other hand, an HTSTA receiver applied to a wireless LAN system that does not include an HT beacon and needs to demodulate a legacy beacon in the HT sequence has a configuration as shown in FIG. That is, in the receiver 40, the radio signal received by the antenna 41 is processed by the filter circuit 42 to pass only a signal in a desired band. The output signal of the filter circuit 42 is converted from a time signal to a frequency signal by the FFT circuit 43. The switch 44 switches the output signal of the FFT circuit 43 to the thinning circuit 45 or the demodulator 46 and outputs it. As shown in FIG. 9, the thinning circuit 45 performs an operation of cutting out only the first 1 / n for each OFDM symbol with respect to the signal input from the switch 44 (in this case, for example, when n = 3). Show.) The demodulator 46 converts the signal input from the switch 44 or the signal input from the thinning circuit 45 into a bit string based on the signal point. The error correction decoder 47 performs error correction decoding on the signal input from the demodulator 46. The MAC circuit 48 reads a frame transmission / reception method, a frame format, and the like based on a signal input from the error correction decoder 47 and outputs received data. The filter circuit 42, the FFT circuit 43, the switch 44, the thinning circuit 45, the demodulator 46, and the error correction decoder 47 constitute a receiving circuit 40a.

  In the above description, the thinning circuit 45 is arranged between the FFT circuit 43 and the demodulator 46. However, the present invention is not limited to this. Other configurations may be adopted as long as the functions equivalent to this configuration are achieved.

  Next, the operation of the wireless LAN system according to the first embodiment will be described. FIG. 10 is a diagram illustrating a state in which HTAP performs transmission suppression for legacy AP. As shown in FIG. 10, when HTAP and legacy AP coexist in the same frequency band, HTAP transmits in the order of legacy beacon, legacy CTS, and HT sequence (HT beacon, HTdata). Thereby, the NAV can be set for the legacy AP, and the HT sequence can be protected from packet collision. Further, by transmitting a legacy beacon, it is possible to notify the legacy AP that another AP exists on the currently used frequency. Here, the legacy beacon and the legacy CTS refer to an 11a type beacon and a CTS in the case of the 5 GHz band. In addition, in the case of the 2.4 GHz band, an 11 format beacon and CTS are pointed out.

  Here, as shown in FIG. 11, the HTAP 110 may simply transmit a CTS immediately before transmitting HT data to occupy a section in which the HT data is transmitted. However, with this method alone, after transmission of HT data is completed, for example, transmission of a signal is started from the legacy STA 114, and it is expected that this signal and the CTS transmitted by the HTAP 110 collide.

  Therefore, as shown in FIG. 10, it is desirable to occupy the wireless medium at all times in all bands. By adopting this method, it is possible to avoid packet collision between the HT terminal and the legacy terminal. In other words, by occupying the wireless medium all the time, there is no possibility that the legacy terminal transmits while the HTAP is transmitting a packet, and a signal notifying that the HTAP occupies the wireless medium is transmitted. Thus, there is no signal from the legacy terminal before the HT sequence. In particular, since it is difficult for the HT terminal to demodulate (or recognize) the signal transmitted from the legacy terminal, the absence of the transmission signal from the legacy terminal before the HT sequence has a great meaning in avoiding a collision. Have.

  Note that the legacy CTS transmitted by the HTAP shown in FIG. 10 may be a legacy CF-pol as shown in FIG.

  Moreover, as shown in FIG. 13, it may be a normal MAC frame in which a period to be protected is specified in duration. The MAC frame format in this case is shown in FIG. However, as shown in FIG. 15, type and subtype other than PS-Poll must be used for the type and subtype included in the frame control. This is because, during PS-Poll, the duration section indicates AID instead of duration (see: IEEE802.11-1999 7.1.3.1.2 Table1-Valid type / subtype combinations).

  Further, as shown in FIG. 16, an HT beacon may be included in the HT sequence. As described above, when the HT beacon is included in the HT sequence, there is an advantage that the HT terminal does not need to demodulate the legacy information such as the legacy beacon and the legacy CTS.

  Further, as shown in FIG. 17, the HT beacon may not be included in the HT sequence. In this case, it is assumed that parameters relating to HT transmission (HT sequence), that is, information relating to the bandwidth to be used, etc. are exchanged in the legacy beacon.

  As described above, according to the wireless LAN system according to the first embodiment, the legacy beacon and the legacy CTS are transmitted as the occupied signals before the HT sequence, so that the legacy terminal recognizes these signals, It can be notified that the HT terminal occupies the wireless medium. In addition, since the HT terminal communicates after transmitting the occupied signal using all frequencies in the n-fold frequency band of the legacy terminal, the transmission is suppressed for the legacy terminal and the radio medium is occupied. HT terminal communication can be performed. Thereby, collision of packets can be avoided and a reduction in throughput can be prevented. As a result, the original transmission speed between HT terminals can be exhibited.

(Second Embodiment)
In the wireless LAN system according to the second embodiment, similarly to the wireless LAN system according to the first embodiment, a signal notifying that the wireless medium is occupied is transmitted, and the time zone for performing the HT sequence is logically set. Occupy the legacy terminal. Here, when legacy AP and HTAP coexist in the same frequency band, transmitting both legacy beacons and legacy CTS prior to the HT sequence as in the first embodiment leads to an increase in overhead. Therefore, in the second embodiment, as shown in FIG. 18, a legacy beacon is not transmitted, but a legacy CTS and an HT sequence (HT beacon, HTdata) are transmitted in this order. Also in this case, as shown in FIG. 19, legacyCF-pol may be used instead of legacyCTS.

  Further, as shown in FIG. 20, a normal MAC frame in which a period to be protected is specified in duration may be used. However, as described in FIGS. 14 and 15, the type and subtype included in the frame control must use a type and subtype other than PS-Poll (see: IEEE 802.11-1999 7.1.3). 1.2 Table1-Valid type / subtype combinations). In this case, as shown in FIG. 21, it is necessary to include an HT beacon in the HT sequence.

  As described above, according to the wireless LAN system according to the second embodiment, it is possible to improve the throughput without causing an increase in overhead.

(Third embodiment)
In the wireless LAN system according to the third embodiment, coexistence of an HT terminal and a legacy terminal is realized. That is, the HT terminal occupies a part of the period of the wireless medium and does not occupy the other part, thereby coexisting with the legacy terminal.

  In the third embodiment, the duration of the legacy MAC frame transmitted by the HT terminal is set as x% (x is 100% or less) of the interval from the end of the legacy MAC frame to the next beacon. The ratio of the communication time between the HT terminal and the legacy terminal can be adjusted according to this ratio (the ratio that the HT terminal occupies a part of the wireless medium). That is, FIG. 22 shows a state in which the 100% HT terminal occupies the interval from the end of the legacy MAC frame to the next beacon. FIG. 23 illustrates a state in which, for example, 70% of the interval from the end of the legacy MAC frame to the next beacon is occupied by the HT terminal, and the remaining 30% is used by the legacy terminal. As a result, the HT terminal and the legacy terminal can coexist. The above “x%” may be a fixed value or may be varied. Further, hereinafter, in the above example, it is considered that the case of x = 100 occupies the wireless medium completely, and the case of x <100 occupies a part of the period of the wireless medium.

  Also, as shown in FIGS. 24 and 25, without transmitting a legacy beacon, the legacy MAC frame is transmitted in the order of HT sequence (HT beacon, HTdata), and the duration of the duration in the legacy MAC frame is set from the end of the legacy MAC frame. You may set as x% (x is 100% or less) of the space | interval to the next legacyMACframe.

  In the above description, the case where the duration is set by the legacy MAC frame is shown, but CTS or legacy CF-pol may be used instead of the legacy MAC frame.

  Subsequently, since it is necessary for HTSTA to know the HT sequence section in which HT transmission is possible, a method for notifying the HT sequence section from HTAP to HTSTA will be described below. As shown in FIG. 26, an HT beacon in which information on the HT sequence section is described is included in the HT sequence. Further, as shown in FIG. 27, an HT beacon in which information related to an HT sequence section is described in the HT sequence, and an HT section end signal may be included at the end of the HT sequence. As a result, the HTSTA that has received the HT beacon can grasp a section in which HT communication is possible.

  As shown in FIG. 26, in the case of a wireless LAN system including an HT beacon in which information related to the HT sequence section is described in the HT sequence, HTSTA adopts a configuration as shown in FIG. That is, the radio signal received by the antenna 50 is demodulated by the receiving circuit 51. The HT section start determination circuit 52 determines that the HT section has started based on the HT beacon included in the demodulated data output from the receiving circuit 51. The counter circuit 53 starts the counter based on the output signal of the HT period start determination circuit 52. This counter counts the time that has elapsed since the start of the HT period. The HT section end determination circuit 54 determines the end of the HT section together with the output of the counter circuit 53 according to the information about the HT section included in the HT beacon. The transmission control circuit 55 controls the transmission circuit 57 based on the output signal of the HT period start determination circuit 52 and the output signal of the HT period end determination circuit 54. The MAC circuit 56 defines a frame transmission / reception method and frame format, which are data transmission / reception units for transmission data, and reads the frame transmission / reception method and frame format from the reception data. Under the control of the transmission control circuit 55 and the MAC circuit 56, the transmission circuit 57 converts the transmission data into a radio signal and transmits it through the antenna 58. With such a configuration, HTSTA can grasp the start and end of the section of the HT sequence. However, the receiving circuit 51 has the same configuration as the receiving circuit 40a shown in FIG. The transmission circuit 57 has the same configuration as the transmission circuit 20a shown in FIG. The antenna 50, the receiving circuit 51, the HT section start determining circuit 52, the counter circuit 53, the HT section end determining circuit 54, the transmission control circuit 55, and the MAC circuit 56 constitute a receiver 59a.

  Further, as shown in FIG. 27, in the case of a wireless LAN system including an HT beacon in which information on an HT sequence section is described in the HT sequence and an HT section end signal at the end of the HT sequence, HTSTA is shown in FIG. The configuration as shown is adopted. Here, since both signals indicating the start and end of the HT sequence are transmitted, the HTSTA can easily grasp the section of the HT sequence. Therefore, the configuration shown in FIG. 28 is the same as the configuration in which the counter circuit 53 is removed.

  In FIG. 29, in HTSTA, the HT section start determination circuit 52 determines that the HT section has started from the HT beacon included in the demodulated data output from the reception circuit 51. The HT section end determination circuit 54 determines the end of the HT section by receiving an HT section end signal. The transmission control circuit 55 controls the transmission circuit 57 based on the output signal of the HT period start determination circuit 52 and the output signal of the HT period end determination circuit 54. Thereby, the start of the HT section can be grasped by the HT beacon included at the head of the HT sequence, and the end of the HT section can be grasped by the HT section end signal included at the end of the HT sequence. You can know the possible sections. The antenna 50, the receiving circuit 51, the HT section start determining circuit 52, the HT section end determining circuit 54, the transmission control circuit 55, and the MAC circuit 56 constitute a receiver 59b.

  As described above, according to the wireless LAN system according to the third embodiment, it is possible to secure a period during which the legacy terminal communicates by changing the occupation period in which the wireless medium is occupied. Therefore, while the HT terminal occupies 100% of the wireless medium, transmission is suppressed in the legacy terminal to avoid packet collision and prevent a decrease in throughput between the HT terminals, while the HT terminal uses the wireless medium. While the terminal is not occupied, the legacy terminal can communicate, so that the HT terminal and the legacy terminal can coexist. Furthermore, since the HT beacon in which information related to the HT sequence section is described is included, the HTSTA can clearly grasp that the communication period has started. Further, when the HTAP transmits an HT section end signal, the HTSTA can clearly grasp that the period of communication has ended without measuring the time from the start. Since the reception side clearly grasps the start and end of the period, it is possible to facilitate the configuration of a system that changes the occupation period in which HTAP and HTSTA occupy a part of the period of the wireless medium.

(Fourth embodiment)
In the wireless LAN system according to the fourth embodiment, an occupancy signal for occupying the wireless medium is intermittently transmitted in order to realize coexistence of the HT terminal and the legacy terminal. Here, “intermittent” means that the occupancy signal is not transmitted at certain time intervals. For example, in the case of the frame configuration shown in FIG. 13, while a legacy beacon is transmitted L (L is a natural number) times, a legacy MAC frame is transmitted m (m is a natural number equal to or less than L) times, and the others are not transmitted. Further, as in the frame configuration shown in FIG. 19, when only the legacy MAC frame is transmitted, if the legacy MAC frame is transmitted P (P is a natural number) times, the legacy MAC frame is not transmitted in the next frame. As a result, the legacy terminal can also transmit a signal in a section where the legacy MAC frame is not transmitted. Thereby, as shown in FIG. 30, the ratio of the communication time of an HT terminal and a legacy terminal can be adjusted. That is, in FIG. 30, assuming that the section in which the HTAP transmits the legacy MAC frame and occupies the wireless medium is (1), and the section in which the HTAP does not transmit the legacy MAC frame and does not occupy the wireless medium is (2), the legacy terminal Can communicate in the section (3).

  Further, as shown in FIG. 31, even if the HTAP transmits a legacy MAC frame and occupies the wireless medium, if it occupies x% of the section (4), the section (5) In the rest (100-x%), the legacy terminal can communicate. In FIG. 31, in the section (2), the HTAP does not occupy the wireless medium without transmitting the legacy MAC frame, so that the legacy terminal can communicate in the section (3).

  In addition, it is also possible to use legacyCTS or legacyCF-pol instead of legacyMACframe.

  As described above, according to the wireless LAN system according to the fourth embodiment, occupancy signals such as legacy MAC frames are intermittently transmitted. Therefore, when transmitting an occupancy signal, the radio medium is occupied by the HT terminal, transmission is suppressed at the legacy terminal, packet collision is avoided, and a decrease in throughput at the HT terminal is prevented. On the other hand, when the occupancy signal is not transmitted, the wireless medium is not occupied by the HT terminal, so that communication is possible with the legacy terminal. As a result, the HT terminal and the legacy terminal can coexist.

(Fifth embodiment)
In the wireless LAN system according to the fifth embodiment, in order to realize coexistence between the HT terminal and the legacy terminal, the coexistence with the legacy terminal is achieved by adjusting how much communication time the HT terminal secures. . In the fifth embodiment, for example, in the case of the frame configuration shown in FIG. 22 and FIG. 23, the number of times the HT sequence occupies x% of the interval from the end of the legacy MAC frame to the next legacy beacon is set to L ( It is assumed that m (m is a natural number equal to or less than L) times during transmission of L times. The remaining Lm times occupy y (y is 100% or less)% of the interval from the end of the legacy MAC frame to the next legacy beacon in the HT sequence.

  In the above description, during the transmission of legacy beacons L times, a method of switching the HT sequence at a ratio of two types (x% and y% of the interval from the end of the legacy MAC frame to the next beacon) is shown. It is not necessarily limited to this, and it may be i types (i = 2 or more positive integers). Also, as shown in FIGS. 24 and 25, the interval from the end point of the legacy MAC frame to the next legacy MAC frame can be adjusted at the above ratio.

  As a result, the ratio of the communication time between the HT terminal and the legacy terminal is adjusted, and both can coexist.

(Sixth embodiment)
In the first to fifth embodiments described above, the transmission time of the HT sequence is logically secured by setting the NAV for the legacy terminal and suppressing the transmission when the HTAP transmits the legacy CTS. The method was shown.

  However, if HTSTA is able to receive legacy CTS, HTSTA needs to be able to recognize that legacy CTS is for securing time for the HT sequence.

  For this reason, in the wireless LAN system according to the sixth embodiment, by setting the receiver address included in the legacy CTS transmitted by HTAP to secure the HT sequence to a specific value, , It notifies that the occupation of the medium by CTS is due to the occupation of the HT sequence. This receiver address constitutes identification information.

  On the other hand, the HTSTA can adopt the configuration shown in FIG. 7 or FIG. That is, the MAC circuit 36 or 48 as a recognition unit for recognizing the receiver address, and when the receiver address is recognized as a specific address, the received signal is demodulated and the received data is output. If the received address is not recognized, a configuration including a receiving circuit 30a or a receiving circuit 40a as a receiving unit that stops demodulation of the received signal is adopted.

  FIG. 32 is a diagram showing a CTS frame format. As shown in FIG. 32, the CTS frame includes a frame control unit 60 as a MAC header, a duration unit 61, a receiver address 62, and an FCS unit 63. Here, when the receiver address 62 is a specific address, the HTSTA can recognize that the received CTS is a CTS for occupying time for the HT sequence. That is, since there is an address that is not normally used in the MAC address, by using the address, it is possible to make HTSTA recognize that the received CTS is for the HT terminal to occupy. .

  Next, the operation when the HTSTA receives a legacy CTS will be described with reference to the flowchart shown in FIG. When the HTSTA receives the legacy CTS (step S1), the MAC circuit 36 or 48 determines whether the receiver address included in the legacy CTS is a specific address (step S2). As a result, if it is a specific address, it is determined that it is a legacy CTS from the HTAP, and preparations for demodulating the HT signal are made (step S3). Then, the HT signal is demodulated, and when the HT period ends (step S4), the process proceeds to step S1 and again waits for reception of legacy CTS. On the other hand, if the receiver address included in the legacy CTS is not a specific address in step S2, it is determined that the CTS is from the legacy terminal, and the receiving circuit 30a or the receiving circuit 40a is stopped (step S5). After the NAV section set by the CTS has elapsed, the receiving circuit 30a or the receiving circuit 40a is operated (step S6), the process proceeds to step S1, and the reception of the legacy CTS is awaited again.

  As described above, according to the wireless LAN system according to the sixth embodiment, in the HT terminal, the legacy CTS is in the receiver address as identification information for recognizing that the signal is for occupying the wireless medium. Since a specific value is used, the HT terminal (STA) can recognize that the CTS has been transmitted to notify the legacy terminal that the wireless medium is occupied. Thereby, in HTSTA, it can be judged whether the data transmitted after CTS is what was transmitted with respect to HTSTA. As a result of the determination, if the data transmitted after the CTS is transmitted to the HTSTA, the data is demodulated, while the data transmitted after the CTS is transmitted to the HTSTA. If not, the reception operation is stopped. As a result, unnecessary operations can be avoided and power consumption can be saved.

  In the wireless LAN systems according to the third to fifth embodiments, when a legacy terminal transmits a very long packet when giving a transmission opportunity to the legacy terminal, a collision between the HT signal and the legacy signal occurs. It is not easy to avoid it completely. However, when the packet transmitted by the legacy terminal is short, the collision can be sufficiently reduced.

(Seventh embodiment)
In the first to sixth embodiments described above, description has been made on the assumption that it is used in the 5 GHz band as a specific example. That is, the legacy terminal is based on the use of the IEEE 802.11a system (OFDM system). In contrast, in the seventh embodiment, a transmitter and a receiver of an HT terminal on the premise that the use in the 2.4 GHz band, that is, the legacy terminal uses the IEEE 802.11 system (DSSS system) will be described.

  FIG. 34 is a block diagram showing a schematic configuration of a transmitter of an HT terminal used in the 2.4 GHz band. In the transmitter 340, transmission data is input to the MAC circuit 341, and the MAC circuit 341 outputs the transmission signal data to the DSSS signal transmission circuit unit 342 when transmitting a signal compatible with the legacy terminal. The radio signal is transmitted through the antenna 344 through the switch unit 343.

  On the other hand, when communication is performed with another HT terminal using a wider frequency band than the legacy terminal, the transmission signal data is output from the MAC circuit 341 to the HT transmission circuit unit 345 and passes through the switch unit 343. The radio signal is transmitted through the antenna 344.

  The HT transmission circuit unit 345 shown in FIG. 34 has the same configuration as the transmission circuit 20a shown in FIG.

  In the following description, a portion including the HT transmission circuit unit 345 and the MAC circuit 341 in FIG. Further, a portion including the DSSS signal transmission circuit unit 342 and the MAC circuit 341 is defined as an occupation signal generation unit 401. That is, by outputting transmission signal data from the MAC circuit 341 included in the occupancy signal generation unit 401 to the DSSS signal transmission circuit 342, a signal compatible with the legacy terminal is transmitted, and the MAC circuit included in the transmission unit 400 It is assumed that a signal compatible with the HT terminal is transmitted by outputting transmission signal data from 341 to the HT transmission circuit 345.

  FIG. 35 is a block diagram showing a detailed configuration of the DSSS signal transmission circuit unit 342 in FIG. The transmission signal data output from the MAC circuit 341 shown in FIG. 34 is subjected to scramble processing (randomized by a specific pattern) by the scramble processing unit 351 shown in FIG. 35 and then binary data in the DQPSK / DBPSK modulation unit 352. To be modulated. The modulated data is subjected to signal spreading in spreading section 353 using spreading code 353a, and then band-limited to 22 MHz in filter section 354. Data output from the filter unit 354 is input to the adder 355, the first frequency conversion unit 356a, and the second frequency conversion unit 356b, respectively. The first frequency conversion unit 356a outputs data obtained by shifting the center frequency by 20 MHz to the adder 355, and the second frequency conversion unit 356b outputs data obtained by shifting the center frequency by 40 MHz to the adder 355. The adder 355 adds the data input from the filter unit 354, the data input from the first frequency conversion unit 356a, and the data input from the second frequency conversion unit 356b. Thereby, when viewed in the frequency direction, it is possible to generate a radio signal in which three DSSS signals are arranged at intervals of 20 MHz.

  FIG. 36 is a block diagram showing a schematic configuration of a receiver of an HT terminal used in the 2.4 GHz band. When the wireless signal is received by the antenna 361 and the switch unit 362 receives a signal compatible with the legacy terminal, the DSSS signal receiving circuit unit 363 demodulates the DSSS signal, and then the demodulated signal data is transmitted to the MAC circuit 364. Output to.

  On the other hand, when communication is performed with the HT terminal using a wider frequency band than the legacy terminal, the signal is demodulated by the HT receiving circuit unit 365 and the demodulated signal data is output to the MAC circuit 346.

  Note that the HT reception circuit unit 365 shown here has the same configuration as the reception circuit 40a shown in FIG.

  FIG. 37 is a block diagram showing a detailed configuration of the DSSS signal receiving circuit unit 363 in FIG. The radio signal output from the antenna 361 shown in FIG. 36 is extracted only by the filter of the 22 MHz band required by the filter unit 371 shown in FIG. 37, and this is despread by applying the spreading code 372a by the despreading unit 372. Processing is performed. The output of the despreading unit 372 is demodulated into binary data by the delay detection unit 373, and the descrambling processing unit 374 performs descrambling processing (cancel randomization by a specific pattern performed on the transmission side). Then, the received signal data obtained is output to the MAC circuit 364 shown in FIG.

  The “frequency bandwidth” in the seventh embodiment can be considered as follows. That is, in the 5 GHz band, as shown in FIG. 38, the frequency bandwidth used by the HT terminal is n times that of the legacy terminal (n = 3 in the figure). On the other hand, in the 2.4 GHz band, the frequency bandwidth used by the HT terminal is n times 20 MHz as shown in FIG. 39, whereas the frequency bandwidth used by the legacy terminal is 22 MHz. The frequency bandwidth used by the HT terminal cannot be defined as n times the frequency band used by the legacy terminal.

  However, it is the same in FIG. 38 and FIG. 39 in that the occupied signal is “a signal compatible with the legacy terminal using all frequencies in the frequency band fh used by the HT terminal”. it can.

  Therefore, also in the 2.4 GHz band, the same effect as that shown in the first to sixth embodiments can be obtained by using the occupied signal having compatibility with the legacy terminal shown in FIG.

2 is a block diagram of an HTSTA transmitter. FIG. It is a block diagram of the transmitter of legacySTA. It is a block diagram of the transmitter of HTAP. It is a block diagram of the symbol repetition apparatus of the transmitter of HTAP. It is a figure which shows the signal which the transmitter of HTAP transmits. It is a figure which shows the signal which the transmitter of HTAP transmits. 2 is a block diagram of an HTSTA receiver. FIG. 2 is a block diagram of an HTSTA receiver. FIG. It is a block diagram of a thinning-out circuit of an HTSTA receiver. It is a figure which shows a mode that HTAP performs transmission suppression with respect to legacyAP. It is a figure which shows a mode that a packet collides when an HT terminal and a legacy terminal coexist. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows a MAC frame format. It is a figure which shows a MAC frame format. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP transmits. It is a figure which shows the structure of the data which HTAP and legacyAP transmit. It is a figure which shows the structure of the data which HTAP and legacyAP transmit. It is a figure which shows the structure of the data which HTAP and legacyAP transmit. It is a block diagram of HTSTA. It is a block diagram of HTSTA. It is a figure which shows the area which can transmit HTAP and legacyAP. It is a figure which shows the area which can transmit HTAP and legacyAP. It is a figure which shows a CTS frame format. It is a flowchart which shows operation | movement when HTSTA receives legacyCTS. It is a block diagram which shows schematic structure of the transmitter of the HT terminal used by 2.4 GHz band. It is a block diagram which shows the detailed structure of a DSSS signal transmission circuit part. It is a block diagram which shows schematic structure of the receiver of the HT terminal used by 2.4 GHz band. 3 is a block diagram showing a detailed configuration of a DSSS signal receiving circuit unit 363. FIG. It is a figure which shows the frequency bandwidth which a HT terminal uses in a 5 GHz band, and the frequency bandwidth used when transmitting a signal compatible with a legacy terminal. It is a figure which shows the frequency bandwidth which a HT terminal uses in a 2.4 GHz band, and the frequency bandwidth used when transmitting a signal compatible with a legacy terminal. It is a figure which shows the frequency band which an HT terminal and a legacy terminal use. It is a figure which shows schematic structure of the conventional wireless LAN system. It is a figure which shows the area of the data transmitted with the conventional wireless LAN system. It is a figure which shows the area of the data transmitted with the conventional wireless LAN system. It is a figure which shows a CTS frame format. It is a figure which shows the area of the data transmitted with the conventional wireless LAN system. It is a figure which shows HT sequence. It is a figure which shows a mode that a packet collides when an HT terminal and a legacy terminal coexist.

Explanation of symbols

20 HTAP transmitter 20a transmission circuit 24 switch 25 symbol repetition circuit 30 receiver 30a reception circuit 36 MAC circuit 40 receiver 40a reception circuit 45 decimation circuit 46 demodulator 48 MAC circuit 50 antenna 51 reception circuit 52 HT section start determination Circuit 53 Counter circuit 54 HT section end determination circuit 55 Transmission control circuit 59a, 59b Receiver 300 Transmitter 301 Occupied signal generator 340 Transmitter 356a First frequency converter 356b Second frequency converter 355 Adder 400 Transmitter 401 Occupied signal generator

Claims (16)

A transmitter applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system and used in the first radio communication system A communication system including a receiver applied to a second wireless communication system that uses a second frequency band wider than the first frequency band,
The transmitter is
An occupancy signal generator that generates an occupancy signal that is compatible with the first radio communication system and notifies the first radio communication system that the second radio communication system occupies a radio medium. When,
Using all frequencies in the second frequency band, wherein after transmitting the occupancy signal, transmits a start signal notifying that period in which the communication by the second wireless communication system starts continuously And a transmitter for performing communication in the second wireless communication system thereafter ,
The receiver
On the basis of the transmitter to the start signal received in succession with the occupation signal, the second wireless communication system comprising: a start determination unit that determines the start of the period to occupy the wireless medium communication system. The occupancy signal generator sets information for designating a period during which the second radio communication system completely occupies a radio medium for the occupancy signal,
2. The communication system according to claim 1, wherein the transmission unit occupies a wireless medium within the period and performs communication in the second wireless communication system. The occupation signal generating unit, with respect to the occupancy signal, and setting information which the second wireless communication system occupies a portion of the period of the wireless medium,
2. The communication system according to claim 1, wherein the transmission unit occupies a wireless medium within the partial period based on the information and performs communication in the second wireless communication system.   4. The communication system according to claim 1, wherein a bandwidth of the second frequency band is n times (n is a natural number) of the first frequency band. 5.   5. The communication system according to claim 4, wherein the occupying signal generation unit includes a symbol repeating unit that repeatedly outputs transmission data corresponding to the occupying signal n times (n is a natural number) in a predetermined symbol unit.   The communication system according to claim 1, wherein the occupying signal generation unit intermittently generates the occupying signal.   The communication system according to any one of claims 1 to 6, wherein the transmission unit transmits an end signal notifying that a period for performing communication in the second wireless communication system ends. The occupation signal generating unit according to any one of claims 7 to identification information for recognizing the start signal in the second radio communication system from claim 1, characterized in that setting the start signal Communications system. The occupied signal generator is
Converting the center frequency of the input signal to a predetermined frequency, and outputting at least one frequency conversion unit;
The communication system according to claim 1, further comprising: an addition unit that adds the input signal and the signal output from the frequency conversion unit. The receiver
A thinning circuit that cuts out and outputs 1 / n of the occupied signal received from the transmitter;
The communication system according to claim 3, further comprising: a demodulator that demodulates a signal input from the thinning circuit and outputs received data. The receiver
Based on the start signal received from the transmitter, a start determination unit that determines the start of a period in which the second wireless communication system occupies a wireless medium;
A measuring unit for measuring a time elapsed after the period starts,
An end determination unit that determines the end of the period based on the time elapsed from the start of the period and the start signal;
The communication system according to claim 1, further comprising: a control unit that outputs a signal for notifying the determination result of the start and end of the period. The receiver
Based on the start signal received from the transmitter, a start determination unit that determines the start of a period in which the second wireless communication system occupies a wireless medium;
An end determination unit that determines the end of the period based on the end signal received from the transmitter;
The communication system according to claim 7, further comprising: a control unit that outputs a signal for notifying the determination result of the start and end of the period. The receiver
A recognition unit for recognizing the identification information based on the occupied signal received from the transmitter;
A receiver that demodulates a received signal and outputs received data when the identification information is recognized, and a receiving unit that stops a receiving operation when the identification information is not recognized. The communication system according to claim 8. A transmitter applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system,
An occupancy signal generator that generates an occupancy signal that is compatible with the first radio communication system and notifies the first radio communication system that the second radio communication system occupies a radio medium. When,
After transmitting the occupancy signal using all frequencies in the second frequency band, continuously transmitting a start signal notifying that a period for performing communication in the second wireless communication system starts. And a transmitter that performs communication in the second wireless communication system thereafter . A receiver applied to a second wireless communication system that uses a second frequency band that is wider than the first frequency band used in the first wireless communication system,
After receiving an occupancy signal from the transmitter that is compatible with the first radio communication system and notifies the first radio communication system that the second radio communication system occupies the radio medium , Continuously receiving a start signal notifying that a period for performing communication in the second wireless communication system starts, and then , based on the start signal, the second wireless communication system occupies a wireless medium A start determination unit for determining the start of the period;
A measuring unit for measuring a time elapsed after the period starts,
An end determination unit that determines the end of the period based on the time elapsed from the start of the period and the start signal;
And a control unit that outputs a signal for notifying the determination result of the start and end of the period. A transmitter applied to a second radio communication system that uses a second frequency band that is wider than the first frequency band used in the first radio communication system and used in the first radio communication system A communication method of a communication system including a receiver applied to a second wireless communication system that uses a second frequency band wider than the first frequency band,
In the transmitter,
Generating an occupation signal that is compatible with the first wireless communication system and notifies the first wireless communication system that the second wireless communication system occupies a wireless medium;
After transmitting the occupancy signal using all frequencies in the second frequency band, continuously transmitting a start signal notifying that a period for performing communication in the second wireless communication system starts. And then performing communication in the second wireless communication system,
In the receiver,
Receiving the start signal continuously from the transmitter with the occupancy signal ;
Determining the start of a period during which the second wireless communication system occupies a wireless medium based on the received start signal.

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