JP2011205575A - Wireless communication system and wireless device to be used for the same - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a wireless communication system which improves throughput of data transmission in cells with lower priorities.SOLUTION: An access point 1 determines an open requesting data channel from overlapping data channels among data channels which are scheduled to be used by itself and data channels which are scheduled to be used by an access point 2, and sends the determined open requesting data channel to the access point 2. The access point 2 determines a data channel to open out of the open requesting data channels and the data channels which is scheduled to be used by itself, and sends the determined data channel to the access point 1. The access point 1 shares the opened data channels with a mobile terminal 11 within a cell C1, and sends/receives data frames to/from the mobile terminals 11 using the shared data channel.

Description

  The present invention relates to a radio communication system and a radio apparatus used therefor, and more particularly to a radio communication system capable of effectively using radio resources and a radio apparatus used therefor.

  Conventionally, a wireless communication system that efficiently shares channel selection information while avoiding interference with other wireless systems is known (Non-Patent Document 1).

  This wireless communication system includes an access point and a mobile terminal. The access point periodically selects a common control channel used for transmission / reception of control information from 16 common control channels existing in the band of 2402 to 2481 MHz by the frequency hopping method, and the selected common control channel is unused. In some cases, data channel selection information for selecting a data channel used for data communication is periodically transmitted to the mobile terminal.

  The access point periodically receives the data channel determined by the mobile terminal using the data channel selection information from the mobile terminal and shares the data channel.

  Thereafter, the access point and the mobile terminal transmit and receive data frames in a time division manner using the data channel.

Hitoshi Yano, Yoshihide Tsuji, Yasuo Suzuki, Seiji Tsukamoto, Makoto Taromaru, Masazumi Ueha, “Study on physical channel configuration of dynamic spectrum access system for high efficiency frequency sharing in ISM band,” IEICE Technical Report SR2008-98 ( 2009-03).

  However, in the conventional wireless communication system, when a plurality of access points are arranged close to each other, the channel selection information of each cell becomes almost the same content. There is a problem that throughput decreases.

  Accordingly, the present invention has been made to solve such a problem, and an object thereof is to provide a wireless communication system capable of improving the throughput of data transmission in a cell having a low priority.

  Another object of the present invention is to provide a radio apparatus used in a radio communication system capable of improving data transmission throughput in a cell having a low priority.

  According to the present invention, a wireless communication system is a wireless communication system that performs wireless communication in a wireless communication environment in which a plurality of cells each managed by a single base station exist and a plurality of different wireless systems coexist. And first and second wireless devices. The first radio apparatus periodically selects a first common control channel from a frequency band used by a plurality of radio systems by a frequency hopping method, and performs carrier sense on the selected first common control channel. If the selected first common control channel is unused, first data channel selection information for selecting a data channel to be used for data communication using the selected first common control channel Send regularly. The second radio apparatus manages a second cell adjacent to the first cell managed by the first radio apparatus, and performs a second frequency hopping method from a frequency band used by a plurality of radio systems. When the common control channel is selected periodically, carrier sense is performed on the selected second common control channel, and the selected second common control channel is unused, the selected second common control channel is selected. The second data channel selection information for selecting a data channel to be used for data communication is transmitted periodically. The first radio apparatus receives the second data channel selection information from the second radio apparatus using the second common control channel as necessary, and the received second data channel selection information. Based on the first data channel selection information and the first data channel selection information, and determines a release request data channel for requesting the second wireless device to release from among the overlapping data channels, and the determination The released request data channel is transmitted to the second radio apparatus using the second common control channel.

  Preferably, when the second wireless device receives the release request data channel from the first wireless device using the second common control channel, the second wireless device transmits the release request data channel to the first wireless device based on the second data channel selection information. The data channel to be released is determined, the data channel to be released is deleted from the second data channel selection information, and the released data channel is transmitted to the first radio apparatus using the second common control channel.

  Preferably, when the first wireless device receives the released data channel from the second wireless device using the second common control channel, the first wireless device receives the data channel scheduled to be used by the second wireless device. One data channel selection information is deleted and the released data channel is added to the first data channel.

  Further, according to the present invention, the radio apparatus is a radio communication system that performs radio communication in a radio communication environment in which a plurality of cells each managed by one base station exist and a plurality of different radio systems are mixed. A wireless device used includes a selection unit, a transmission unit, a reception unit, and a channel determination unit. The selection means periodically selects a common control channel from a frequency band used by a plurality of wireless systems by a frequency hopping method. The transmission means performs carrier sense on the first common control channel selected by the selection means based on the received signal strength information in the frequency band, and when the selected first common control channel is unused. First data channel selection information for selecting a data channel to be used for data communication is periodically transmitted using the first common control channel. The reception unit measures reception signal strength in the frequency band, generates reception signal strength information related to the first common control channel, outputs the generated reception signal strength information to the transmission unit, and manages the radio device Second data channel selection information used for data communication by another wireless device managing the second cell adjacent to the first cell is transmitted from another wireless device using the second common control channel as necessary. Receive. The channel determination means determines an overlapping data channel based on the first and second data channel selection information, and requests an opening request data channel from another overlapping data channel to another wireless device. To decide. Then, the transmitting means further transmits the determined release request data channel to another wireless device using the second common control channel.

  Preferably, the channel determining means receives the release request data channel from the other radio apparatus using the first common control channel, and receives the release request data channel from the other radio apparatus based on the first data channel selection information. The data channel to be released is determined, the data channel to be released is deleted from the first data channel selection information, and the data channel to be released is transmitted to another wireless device using the first common control channel.

  Preferably, when the receiving unit receives the released data channel from the other wireless device using the second common control channel, the transmitting unit receives the data channel scheduled to be used by the other wireless device as the first data channel. The data channel that is deleted from the data channel selection information and released is added to the first data channel selection information.

  In the wireless communication system according to the embodiment of the present invention, when the first wireless device has a low priority due to a cause such as being turned on later than the second wireless device, the second wireless device is moved. As the terminal, the release request data channel is transmitted to the second wireless device, and the second wireless device adjusts the first wireless device so that the first wireless device can use a part of the channel scheduled to be used.

  Therefore, the first wireless device can use the data channel, and the throughput of data transmission in the cell managed by the first wireless device can be improved.

1 is a schematic diagram of a radio communication system according to an embodiment of the present invention. It is a block diagram of the access point shown in FIG. It is a block diagram of the mobile terminal shown in FIG. It is a block diagram of the channel in embodiment of this invention. It is a block diagram of the time frame of a common control channel. It is a block diagram of a control information frame. It is a figure which shows the hopping pattern of a common control channel. It is a figure for demonstrating the method of sharing the data channel used for communication of a data frame between an access point and a mobile terminal. It is a figure which shows the example of data channel selection information. 6 is a flowchart for explaining operations of an access point and a mobile terminal belonging to one cell of the wireless communication system. It is a flowchart for demonstrating the determination of the data channel between access points.

  Embodiments of the present invention will be described in detail with reference to the drawings. In the drawings, the same or corresponding parts are denoted by the same reference numerals and description thereof will not be repeated.

  FIG. 1 is a schematic diagram of a radio communication system according to an embodiment of the present invention. A wireless communication system 100 according to an embodiment of the present invention includes access points (AP: Access Point) 1 to i (i is an integer of 2 or more) and mobile terminals (MS: Mobile Station) 11 to 1i.

  The access point 1 and the mobile terminal 11 are arranged in the cell C1. The access point 2 and the mobile terminal 12 are arranged in the cell C2. Hereinafter, similarly, the access point i and the mobile terminal 1i are arranged in the cell Ci.

  Although not shown in FIG. 1, there are an access point and a mobile terminal that perform wireless communication by a CSMA / CA (Carrier Sense Multiple Access Collision Avidance) method, and an FH-SS (Frequency-Hopping Spread Spread). There are also access points and mobile terminals that perform wireless communication according to a method.

  Therefore, the access points 1 to i and the mobile terminals 11 to 1 i can be used in a wireless communication environment in which a plurality of wireless systems such as a CSMA / CA wireless system and an FH-SS wireless system coexist and coexist. The frequency resource usage state that changes with time is accurately grasped, and an appropriate transmission frequency (frequency channel) is selected to transmit data within each cell C1 to Ci. That is, the access points 1 to i and the mobile terminals 11 to 1 i transmit data in the cells C 1 to Ci by a DSA (Dynamic Spectrum Access) system.

  In addition, each of the access points 1 to i has a lower priority than the adjacent access point due to, for example, being turned on later than an adjacent access point that manages cells adjacent to the cells C1 to Ci that it manages. In this case, the data channel used for data communication is determined by a method described later.

  In FIG. 1, only one access point and one mobile terminal are shown in each cell C1 to Ci, but actually, each cell C1 to Ci includes a plurality of cells. There is a mobile terminal.

  FIG. 2 is a block diagram of the access point 1 shown in FIG. The access point 1 includes an antenna 101, a transmission unit 102, a reception unit 103, a channel determination unit 104, a selection unit 105, a hopping table 106, and a synchronization establishment unit 107.

  The antenna 101 receives a control information frame or data frame from the access points 2 and 3 of the cells C2 and C3 adjacent to the cell C1 or the mobile terminal 11, and outputs the received control information frame or data frame to the receiving means 103. . The antenna 101 receives a control information frame or data frame from the transmission means 102 and transmits the received control information frame or data frame to the access points 2 and 3 or the mobile terminal 11.

  Transmitting means 102 operates in synchronization with the clock received from synchronization establishing means 107. Then, when the access point 1 is powered on, the transmitting unit 102 receives received signal strength information from the receiving unit 103 for each of 80 channels CH1 to CH80 described later, and based on the received received signal strength information. Carrier sense is performed, and the result of the carrier sense is held and output to the selection means 105. Thereafter, the transmission means 102 always receives the received signal strength information from the receiving means 103, performs carrier sense in each of the channels CH1 to CH80 based on the received received signal strength information, and determines the usage status of each channel CH1 to CH80. Detect and hold.

  Further, the transmission unit 102 receives a common control channel used for transmission of the control information frame from the selection unit 105 in units of time frames to be described later. This control information frame is a frame including data channel selection information indicating a data channel used by the access points 2 and 3 or the mobile terminal 11 for data communication. Then, the transmission means 102 performs carrier sense on the common control channel based on the received signal strength information received from the reception means 103, and if the common control channel is not used by another access point or mobile terminal, the data channel selection A control information frame including information is generated, and the generated control information frame is transmitted to the access points 2 and 3 and the mobile terminal 11 in a time division manner within the time frame. That is, the transmission means 102 transmits a control information frame to the access points 2 and 3 and the mobile terminal 11 by the CSMA / CA method and the TDMA (Time Division Multiple Access) method. Then, the transmission means 102 outputs the data channel selection information to the channel determination means 104.

  On the other hand, when the common control channel is used by another access point or a mobile terminal, the transmission means 102 stops transmission of the control information frame to the access points 2 and 3 and the mobile terminal 11, and the next time frame The control information frame is tried to be transmitted to the access points 2 and 3 and the mobile terminal 11.

  Further, the transmission means 102 receives from the reception means 103 a data channel that the mobile terminal 11 is scheduled to use for data communication. Then, the transmission unit 102 generates a data frame, performs carrier sense on the data channel received from the reception unit 103 based on the received signal strength information received from the reception unit 103, and uses an unused data channel. The data frame is transmitted to the mobile terminal 11 in a time division manner.

  Further, when receiving the release request data channel requesting release from the channel determination means 104, the transmission means 102 generates a control information frame including the received release request data channel, and transmits the generated control information frame to the antenna 101. Send through.

  Further, when the transmission unit 102 receives the released data channel from the channel determination unit 104, the transmission unit 102 transmits a control information frame including the received data channel via the antenna 101.

  The receiving means 103 constantly measures the received signal strength information regarding each of the 80 channels CH1 to CH80 via the antenna 101, and outputs the received signal strength information to the transmitting means 102. The receiving unit 103 receives a control information frame or a data frame from the antenna 101. Then, the receiving means 103 extracts the data channel that the access point 2 or 3 or the mobile terminal 11 is scheduled to use for data communication from the control information frame, and outputs the extracted data channel to the transmitting means 102 and the channel determining means 104. To do.

  The receiving unit 103 receives a data frame from the mobile terminal 11 via the antenna 101 and outputs the received data frame to the transmitting unit 102.

  Channel determining means 104 operates in synchronization with the clock received from synchronization establishing means 107. Then, the channel determination means 104 receives from the transmission means 102 data channel selection information DCSI1 (= map indicating the use status of the channels CH1 to CH80) for selecting a data channel used by the access point 1 for data communication. The receiving means 103 receives data channel selection information DCSI2 (= map indicating the usage status of channels CH1 to CH80) for selecting the data channel used by the access points 2 and 3 for data communication.

  Thereafter, the channel determination means 104 determines an overlapping data channel based on the two data channel selection information DCSI1 and DCSI2, and releases it to the other access points 2 and 3 from the determined overlapping data channel. The release request data channel for requesting is determined, and the determined release request data channel is output to the transmission means 102.

  Further, when receiving the release request data channel from the receiving means 103, the channel determination means 104 determines the data channel to be released based on the release request data channel and the data channel selection information DCSI1, and the determined data to be released. The channel is output to the transmission means 102. Then, the channel determination unit 104 deletes the released data channel from the data channel selection information DCSI1.

  Further, when the channel determining unit 104 receives the released data channel from the receiving unit 103, the channel determining unit 104 deletes the data channel scheduled to be used by the other access points 2 and 3 from the data channel selection information DCSI1, and is released. The added data channel is added to the data channel selection information DCSI1.

  The selection unit 105 operates in synchronization with the clock received from the synchronization establishment unit 107. Then, the selection unit 105 receives the result of carrier sense in each of the channels CH1 to CH80 from the transmission unit 102, and based on the received carrier sense result, common control with a high ratio used by other access points is performed. A group of channels is selected, and any one common control channel included in the selected group is selected as the initial common control channel.

  Thereafter, the selection unit 105 refers to the hopping table 106 for each time frame, hops the initial common control channel, and outputs the hopped common control channel to the transmission unit 102.

  Furthermore, after that, the selection unit 105 refers to the hopping table 106 in the next time frame, hops the common control channel, and outputs the hopped common control channel to the transmission unit 102.

  The hopping table 106 stores the hopping pattern of the common control channel. The synchronization establishing means 107 receives a GPS signal from, for example, a GPS (Global Positioning System) satellite (not shown), and generates a clock based on the received GPS signal. Then, the synchronization establishment unit 107 outputs the generated clock to the transmission unit 102, the channel determination unit 104, and the selection unit 105.

  Each of the access points 2 to i shown in FIG. 1 has the same configuration as that of the access point 1 shown in FIG.

  FIG. 3 is a block diagram of the mobile terminal 11 shown in FIG. The mobile terminal 11 includes an antenna 111, a transmission unit 112, a reception unit 113, a channel determination unit 114, and a synchronization establishment unit 115.

  Antenna 111 receives a control information frame including data channel selection information from access point 1 and an access point other than access point 1, and outputs the received control information frame to receiving means 113. Further, the antenna 111 receives a control information frame or data frame from the transmission unit 112 and transmits the received control information frame or data frame to the access point 1.

  The transmission unit 112 operates in synchronization with the clock received from the synchronization establishment unit 115. Then, the transmission means 112 receives the received signal strength information from the receiving means 113, performs carrier sense on each of the channels CH1 to CH80 based on the received received signal strength, holds the result of the carrier sense, and determines the channel. To 114.

  The transmission unit 112 receives a data channel used by the mobile terminal 11 for data communication from the channel determination unit 114, and receives a common control channel used by the access point 1 for transmission of the control information frame from the reception unit 113.

  Then, the transmission means 112 generates a control information frame including data channel selection information indicating the received data channel, and transmits the generated control information frame to the access point 1 through the common control channel.

  Further, the transmission means 112 generates a data frame. Then, the transmission unit 112 performs carrier sense on the data channel scheduled to be used for data communication based on the received signal strength information received from the reception unit 113, and uses the unused data channel to generate the generated data frame. Is transmitted to the access point 1 in a time division manner.

  The receiving means 113 constantly measures the received signal strength information regarding each of the 80 channels CH1 to CH80 via the antenna 111, and outputs the received signal strength information to the transmitting means 112.

  The receiving means 113 detects the arrival of a frame via the antenna 111 with the number of channels that can be simultaneously received by the mobile terminal 11 (that is, the reception bandwidth of the mobile terminal 11). A control information frame including data channel selection information is received from the access point, and the channel when the control information frame is received is detected as a common control channel. The receiving unit 113 outputs the detected common control channel to the transmitting unit 112 and outputs the received control information frame to the channel determining unit 114.

  Further, the reception unit 113 detects arrival of a frame with the reception bandwidth of the mobile terminal 11, receives a data frame, and outputs the received data frame to the transmission unit 112.

  Channel determining means 114 operates in synchronization with the clock received from synchronization establishing means 115. Then, the channel determination unit 114 receives the control information frame including the data channel selection information from the reception unit 113 and receives the result of carrier sense in each channel CH1 to CH80 from the transmission unit 112. Then, the channel determination means 114 determines the data channel that the mobile terminal 11 uses for data communication based on the data channel selection information and the result of carrier sense in each of the channels CH1 to CH80, and transmits the determined data channel. To 112.

  The synchronization establishment unit 115 generates a clock by the same method as the synchronization establishment unit 107 described above, and outputs the generated clock to the transmission unit 112 and the channel determination unit 114.

  Note that each of the mobile terminals 12 to 1i shown in FIG. 1 has the same configuration as the mobile terminal 11 shown in FIG.

  FIG. 4 is a configuration diagram of channels in the embodiment of the present invention. In the embodiment of the present invention, a frequency band of 2402 MHz to 2481 MHz is used. Channels CH1 to CH80 each have a center frequency of 2402 MHz to 2481 MHz and have a signal bandwidth of 1 MHz.

  The common control channels CCH1 to CCH16 are composed of 16 channels whose channel numbers end with “1” or “6”. These frequencies are the same as the transmission frequencies used by the IEEE802.11 wireless LAN (Local Area Network) operated in the frequency band (except for the frequencies of the common control channels CCH1, CCH2, and CCH16). .

  Of the 80 channels CH1 to CH80, 16 common control channels CCH1 to CCH16 are preferentially used for transmission of control information frames, and the remaining 64 channels are used for transmission of data frames.

  Note that the common control channel that is not used for transmission of the control information frame can be temporarily used for transmission of the data frame.

  FIG. 5 is a configuration diagram of a time frame of the common control channel. The time frame has a length of 5 ms. The time frame includes a sensing period, four downlinks DL1 to DL4, and four uplinks UL1 to UL4.

  Each of the four downlinks DL1 to DL4 and the four uplinks UL1 to UL4 constitutes a slot.

  The sensing period has a length of 200 μs, and each of the four downlinks DL1 to DL4 and the four uplinks UL1 to UL4 has a length of 600 μs.

The length of the sensing period is set to 200 μs for the following reason. In ERP-OFDM of IEEE802.11a or IEEE802.11g, the sensing period is longer than 169 μs which is the maximum waiting time (DIFS + contention slot length × CW _min ) required to start transmission of the first data frame This is to prevent the transmission opportunity of the wireless LAN sharing the same frequency band as the DSA system as much as possible by increasing the length.

  The sensing period is used for observing the usage status of each frequency channel CH1 to CH80.

  Each of the four downlinks DL1 to DL4 and the four uplinks UL1 to UL4 is used for transmission of control information.

  More specifically, the three uplink UL1 to UL3 and the three downlink DL1 to DL3 specify the data transmission node and the reception node in the next time frame and the selection of the frequency channel used at that time. Used for information exchange.

  In this case, each of the cells C1 to Ci selects and uses a slot having the same number on the same common control channel in both the uplink and the downlink. Therefore, a maximum of 48 cells (= 16 × 3) can be operated simultaneously in the vicinity.

  Each of the cells C1 to Ci changes the common control channel used for each time frame in accordance with a hopping pattern described later, and increments the slot number to be used at the same time. By averaging the probability of occurrence of interference in the frequency direction and the time direction, even when some frequency channels are occupied by other radio systems, the fairness of transmission opportunities of control information between cells This is to ensure

  UL4, which is the fourth uplink slot, is used for control information other than channel selection information indicating a channel selected for data transmission (for example, location registration request from mobile terminal to access point and connection establishment request). Used for transmission.

  The multiple access in this case is random access in each of the cells C1 to Ci using the same common control channel.

  DL4, which is the fourth slot of the downlink, constitutes a super time frame by a plurality of (about 20 to 30) time frames, and is used for transmission such as a broadcast channel, location registration confirmation, paging and connection establishment confirmation. It is done. At this time, multiple access between cells using the same common control channel is performed by TDMA in units of time frames.

  FIG. 6 is a configuration diagram of a control information frame. The control information frame CTLF has a length of 544 μs and includes a preamble, a physical header, and data.

  The preamble has a length of 204.8 μs and is set at the head of the control information frame CTLF. The physical header has a length of 41.6 μs and is set following the preamble. The data has a length of 297.6 μs and is set at the end of the control information frame CTLF following the physical header.

  The guard time 1 has a length of 24 μs and is set before the control information frame CTLF. The guard time 2 has a length of 32 μs and is set after the control information frame CTLF.

  The total length of the guard times 1 and 2 and the control information frame CTLF is set to 600 μs which is equal to the length of one slot.

  The preamble is composed of eight short preambles SP (short preamble) and two long preambles (long preamble).

  Each of the eight short preambles SP has a length of 8 symbols, and each of the two long preambles has a length of 32 symbols. As a result, the preamble has a length of 128 symbols (= 204.8 μs).

  The short preamble SP is used for automatic gain control AGC (Auto Gain Control) adjustment and frequency offset compensation. Note that the maximum allowable frequency offset in this format is set to 7.8 ppm.

  The long preamble is used for residual frequency offset compensation, reception timing synchronization, and propagation path estimation.

  The physical header includes a rate, a reservation, a length, a parity, and a tail. The rate has a length of 6 bits, the reservation has a length of 1 bit, the length has a length of 12 bits, the parity has a length of 1 bit, Has a length of 6 bits. As a result, the physical header has a length of 26 symbols (= 41.6 μs).

  The rate indicates a modulation scheme, a coding rate, and the number of transmission antennas. The length indicates the length of the data portion with the symbol length (= 1.6 μs) as a unit. In the tail, “0”, which is a known bit, is set.

  The reason why the length has a length of 12 bits is that the length of 12 bits is the minimum number of bits necessary for expressing the length of the time frame (= 5 ms).

  The data includes a service, a type, a subtype, an AP-ID, a Tx-ID, an Rx-ID, a Tx-BW, an Rx-BW, a map, a CRC, and a tail.

  The service has a length of 16 bits, the type has a length of 8 bits, the subtype has a length of 8 bits, and the AP-ID has a length of 16 bits.

  Each of Tx-ID and Rx-ID has a length of 8 bits. Each of Tx-BW and Rx-BW has a length of 2 bits. The map has a length of 80 bits, the CRC has a length of 32 bits, and the tail has a length of 6 bits.

  As a result, the data has a length of 186 symbols (= 297.6 μs).

  The service consists of a descrambling sequence and spare bits. The type and subtype specify the frame type. AP-ID indicates the number of a base station (cell). Tx-ID indicates the intra-cell ID of the transmission node. Rx-ID indicates the intra-cell ID of the receiving node.

  Tx-BW indicates the reception bandwidth of the transmission node. Rx-BW indicates the reception bandwidth of the reception node. The map indicates the selection status of the used frequency channel. CRC consists of CRC-32 parity bits. The tail consists of a channel decoder trellis termination sequence.

  The map has a structure in which “1” or “0” is stored in association with channels CH1 to CH80. “1” indicates that the corresponding channel is used, and “0” indicates that the corresponding channel is unused.

  FIG. 7 is a diagram showing a hopping pattern of the common control channel. In the radio communication system 100, synchronization is maintained between the cells C1 to Ci. Therefore, all hopping patterns of the common control channel are designed so that no collision occurs with each other.

  In the radio communication system 100 using the DSA system, dynamic channel selection is simultaneously performed in a plurality of cells during data transmission. Therefore, it is desirable that the common control channels used in the cells located in the vicinity are close on the frequency axis from the viewpoint of sharing information between cells.

Therefore, the hopping pattern f _hop (n, j) (n and j are positive integers) of the common control channel in the wireless communication system 100 is expressed by the following equation.

  In formula (1), [x] represents the maximum integer not exceeding x.

  FIG. 7 shows the hopping pattern represented by the expression (1).

  The type and period of the hopping pattern is “16”, which is the same as the number of common control channels, and each hopping pattern uses all the common control channels once in one period.

  The 16 common control channels are divided into two frequency blocks 1 and 2. The frequency block 1 is divided into two frequency sub-blocks 1 and 2, and the frequency block 2 is divided into two frequency sub-blocks 3 and 4.

  When the common control channel to be used is hopped based on the hopping pattern, the two frequency blocks 1 and 2 are used alternately, the two frequency subblocks 1 and 2 are used alternately, and the two frequency subblocks 3 , 4 are used alternately.

For example, taking the case of using the first hopping pattern f _hop (1, j) as an example, the selected common control channel CCH is transmitted to the frequency sub-block 1 of the frequency block 1 in the first hop (j = 1). belong to. The common control channel CCH selected at the second hop belongs to the frequency sub-block 3 of the frequency block 2, and the frequency sub-block 2 of the frequency block 1 at the third hop and the frequency at the fourth hop. Each belongs to the frequency sub-block 4 of the block 2.

  As a result, as the common control channel CCH to be used, the frequency blocks 1 and 2 are alternately selected, the frequency sub-blocks 1 and 2 are alternately selected in the frequency block 1, and the frequency sub-block in the frequency block 2. Hopping is performed so that 3 and 4 are alternately selected.

The same applies to the case of using other hopping patterns f _hop (2, j) to f _hop (16, j).

  In Expression (1), the first term on the right side represents selection of frequency blocks 1 and 2, the second term on the right side represents selection of frequency sub-blocks 1 and 2 and frequency sub-blocks 3 and 4, and the third term on the right side. Represents a position in the frequency sub-blocks 1 to 4.

When the common control channel CCH to be used is selected based on the first hopping pattern f _hop (1, j), the common control channel CCH1 is selected at the first hop. The common control channel CCH1 exists at the first position in the frequency sub-block 1 of the frequency block 1. In the second hop, the first position in the frequency sub-block 3 of the frequency block 2 is selected. Since the first position in the frequency sub-block 3 is the position of the common control channel CCH9, the common control channel CCH to be used is hopped to the common control channel CCH9 at the second hop.

  Similarly, the common control channel CCH to be used is hopped to the common control channel CCH5 at the third hop, hopped to the common control channel CCH13 at the fourth hop, and then to the common control channel CCH2 at the fifth hop. Hopping, hopping to common control channel CCH10 at the 6th hop, hopping to common control channel CCH6 at the 7th hop, hopping to common control channel CCH14 at the 8th hop, common control channel at the 9th hop Hop to CCH3, hop to common control channel CCH11 at 10th hop, hop to common control channel CCH7 at 11th hop, hop to common control channel CCH15 at 12th hop, common at 13th hop Hop to control channel CCH4 Hopping to the common control channel CCH12 4 th hop, hop to the common control channel CCH8 at the 15 th hop, hop to the common control channel CCH16 at the 16 th hop.

  Thereafter, the first to 16th hops are repeatedly executed.

  As a result, the common control channel CCH to be used is hopped to all of the 16 common control channels CCH1 to CCH16 in one cycle (from the first hop to the 16th hop).

The same applies to the case of using other hopping patterns f _hop (2, j) to f _hop (16, j).

  In the hopping pattern, four common control channels are grouped in numerical order, and each group uses a single frequency sub-block at each time.

  Further, the hopping pattern is also divided into four blocks in the time direction, and each time block corresponds to one obtained by cyclically shifting each other in the frequency sub-block. That is, the hopping patterns belonging to the same group are in a cyclic shift relationship with each other.

  Further, the number of common control channels belonging to each of the frequency sub-blocks 1 to 4 is determined according to the narrowest reception bandwidth among the reception bandwidths of the access points 1 to i and the mobile terminals 11 to 1 i. The number of common control channels belonging to each of frequency blocks 1 and 2 is determined according to the second narrowest reception bandwidth among the reception bandwidths of access points 1 to i and mobile terminals 11 to 1 i. The number of common control channels belonging to each of the frequency blocks 1 and 2 is an integral multiple of the number of common control channels belonging to each of the frequency sub-blocks 1 to 4. The number of channels is an integral multiple of the number of common control channels belonging to each of the frequency blocks 1 and 2.

  In the hopping pattern shown in FIG. 7, the number of common control channels belonging to each of the frequency sub-blocks 1 to 4 is determined to be four according to the reception bandwidth of 20 MHz, and the common control channel belonging to each of the frequency blocks 1 and 2 is determined. Is determined to be 8 according to the reception bandwidth of 40 MHz. The number of common control channels (= 8) belonging to each of frequency blocks 1 and 2 is twice the number of common control channels (= 4) belonging to each of frequency sub-blocks 1 to 4. The number of common control channels (= 16) belonging to the entire blocks 1 and 2 is twice the number of common control channels (= 8) belonging to each of the frequency blocks 1 and 2.

  Due to the characteristics of the hopping pattern described above, control information for cells using hopping patterns belonging to the same group can all be received simultaneously using a radio apparatus having a reception bandwidth of 20 MHz or more. This is because the frequency bandwidth in which four common control channels belonging to one group exist is 20 MHz.

  Therefore, if the hopping patterns of neighboring cells are set to belong to the same group, control information can be shared between different cells relatively easily. In addition, the inhibition of backoff processing of other wireless systems located in the vicinity is reduced, and a decrease in throughput of these systems can be suppressed.

  In the wireless communication system 100, the access points 1 to i and the mobile terminals 11 to 1i have different reception bandwidths, but have a reception bandwidth of at least 20 MHz. In FIG. 1, common control channels belonging to the same group of hopping patterns are set in the adjacent cells C1 to C3 and the cells Ci-1, Ci and the like.

  In each of the access points 1 to i, the hopping table 106 holds the hopping pattern shown in FIG. Therefore, in each of the access points 1 to i, the selection unit 105 selects a common control channel to be used in each time frame with reference to the hopping pattern shown in FIG.

[Data channel sharing between access points and mobile terminals]
FIG. 8 is a diagram for explaining a method of sharing a data channel used for data frame communication between the access points 1 to i and the mobile terminals 11 to 1 i. In FIG. 8, a method of sharing a data channel used for data frame communication between the access point 1 belonging to the cell C1 and the mobile terminal 11 will be described.

  The selection unit 105 of the access point 1 receives the result of carrier sense in each of the channels CH1 to CH80 from the transmission unit 102, and based on the received result of carrier sense, the other access points 2 and 3 by the above-described method. Frequency sub-block 1 is selected as a group having a high ratio of being used.

  Then, the selection means 105 of the access point 1 selects the common control channel CCH1 belonging to the selected frequency subblock 1 as the initial common control channel CCH_ini used by the access point 1. That is, the selection means 105 of the access point 1 selects the common control channel CCH1 at the first hop.

  The transmission means 102 of the access point 1 receives the common control channel CCH1 from the selection means 105, and performs carrier sense on the common control channel CCH1 based on the received signal strength information received from the reception means 103 in the sensing period 1.

  If the common control channel CCH1 is unused as a result of carrier sense, the transmission means 102 of the access point 1 uses a map (= data channel selection information) indicating the usage status for the channels CH1 to CH80 as “1” or “0”. ), And the generated control information frame CTLF1 is transmitted to the mobile terminal 11 in the slot (= DL1) of the time frame TF1 using the common control channel CCH1.

  Then, the reception means 113 of the mobile terminal 11 detects the arrival of a frame in the frequency band (= 2402 to 2481 MHz) of the common control channels CCH1 to CCH16 via the antenna 111, and receives the control information frame CTLF1 on the common control channel CCH1. Then, the received control information frame CTLF1 is output to the channel determining means 114, and the common control channel CCH1 that has received the control information frame CTLF1 is output to the transmitting means 112.

  Thereafter, the channel determination unit 114 of the mobile terminal 11 receives the control information frame CTLF1 from the reception unit 113, refers to the map of the received control information frame CTLF1, and uses the channels CH1 to CH80 observed by the access point 1 To get. Further, the channel determination unit 114 of the mobile terminal 11 receives from the transmission unit 112 the usage status of the channels CH1 to CH80 observed by the transmission unit 112.

  Then, the channel determination unit 114 of the mobile terminal 11 starts from the channels CH1 to CH80 based on the usage status of the channels CH1 to CH80 received from the access point 1 and the usage status of the channels CH1 to CH80 received from the transmission unit 112. Of the 64 channels excluding the common control channels CCH1 to CCH16, an unused channel is determined as the data channel DCH_1 used by the mobile terminal 11 for data frame communication. Then, the channel determination unit 114 of the mobile terminal 11 outputs the determined data channel DCH_1 to the transmission unit 112.

  Thereafter, the transmission means 112 of the mobile terminal 11 receives the data channel DCH_1 from the channel determination means 114 and the common control channel CCH1 from the reception means 113. Then, the transmission means 112 of the mobile terminal 11 generates a control information frame CTLF2 including the data channel DCH_1, and accesses the generated control information frame CTLF2 in the slot (= UL1) of the time frame TF1 using the common control channel CCH1. Send to point 1.

  The receiving means 103 of the access point 1 detects the arrival of a frame via the antenna 101, receives the control information frame CTLF2 through the common control channel CCH1, and outputs the received control information frame CTLF2 to the transmitting means 102.

  Then, the transmission means 102 of the access point 1 detects the data channel DCH_1 included in the control information frame CTLF2 received from the reception means 103, and the data channel used by the mobile terminal 11 for data frame communication is the data channel DCH_1. Detect that.

  As a result, the data channel DCH_1 is shared between the access point 1 and the mobile terminal 11.

  After that, the access point 1 and the mobile terminal 11 select an unused channel at the time of data frame transmission from the data channel DCH_1 by carrier sense, and transmit and receive the data frame DTF1 to each other in a time division manner using the selected channel. To do.

  Note that the reception means 113 of the mobile terminal 11 detects the arrival of a frame in the frequency band (= 2402 to 2481 MHz) of the common control channels CCH1 to CCH16 via the antenna 111. As a result, not only the control information frame CTLF1, When the control information frame CTLF3 from the access point 2 belonging to the cell C2 is received, the control information frame CTLF1 and the control information frame CTLF3 are output to the channel determining means 114.

  Then, the channel determination means 114 of the mobile terminal 11 receives from the transmission means 112 the usage status of the channels CH1 to CH80 included in the control information frame CTLF1, the usage status of the channels CH1 to CH80 included in the control information frame CTLF3, and Based on the usage status of channels CH1 to CH80, data channel DCH_1 is determined by the method described above.

  Thereby, the data channel DCH_1 can be determined from an unused channel in the cell C2 adjacent to the cell C1, and interference between the cells C1 and C2 can be avoided.

  On the other hand, if the common control channel CCH1 is in use as a result of carrier sense on the common control channel CCH1 in the sensing period 1, the transmission means 102 of the access point 1 stops transmission of the control information frame CTLF in the time frame TF1. .

  After the time frame TF1 is completed, when the selection unit 105 of the access point 1 detects the time frame TF2 in synchronization with the clock from the synchronization establishment unit 107, the hopping pattern stored in the hopping table 106 (see FIG. 7) is referred to. Then, the common control channel CCH9 is selected as the common control channel used in the time frame TF2. That is, the common control channel to be used is hopped from the common control channel CCH1 to the common control channel CCH9. Then, the selection means 105 of the access point 1 outputs the selected common control channel CCH9 to the transmission means 102.

  In this case, the selection unit 105 of the access point 1 selects the common control channel CCH9 in the same manner even when the transmission unit 102 does not transmit the control information frame CTLF to the mobile terminal 11 in the time frame TF1, and transmits the same. Output to.

  The transmission means 102 of the access point 1 receives the common control channel CCH9 from the selection means 105, and performs carrier sense on the common control channel CCH9 based on the received signal strength information received from the reception means 103 in the sensing period 2. Then, if the common control channel CCH9 is not used, the transmission means 102 of the access point 1 includes a map (= data channel selection information) indicating the usage status for the channels CH1 to CH80 as “1” or “0”. A control information frame CTLF4 is generated, and the generated control information frame CTLF4 is transmitted to the mobile terminal 11 in the slot (= DL2) of the time frame TF2 using the common control channel CCH9.

  Then, the reception means 113 of the mobile terminal 11 detects the arrival of a frame in the frequency band (= 2402 to 2481 MHz) of the common control channels CCH1 to CCH16 via the antenna 111, and receives the control information frame CTLF4 on the common control channel CCH9. Then, the received control information frame CTLF4 is output to the channel determining means 114, and the common control channel CCH9 receiving the control information frame CTLF4 is output to the transmitting means 112.

  Thereafter, the channel determination unit 114 of the mobile terminal 11 receives the control information frame CTLF4 from the reception unit 113, refers to the map of the received control information frame CTLF4, and uses the channels CH1 to CH80 observed by the access point 1 To get. Further, the channel determination unit 114 of the mobile terminal 11 receives from the transmission unit 112 the usage status of the channels CH1 to CH80 observed by the transmission unit 112.

  Then, the channel determination unit 114 of the mobile terminal 11 starts from the channels CH1 to CH80 based on the usage status of the channels CH1 to CH80 received from the access point 1 and the usage status of the channels CH1 to CH80 received from the transmission unit 112. Of the 64 channels excluding the common control channels CCH1 to CCH16, an unused channel is determined as the data channel DCH_2 used by the mobile terminal 11 for data frame communication. Then, the channel determination unit 114 of the mobile terminal 11 outputs the determined data channel DCH_2 to the transmission unit 112.

  Thereafter, the transmission means 112 of the mobile terminal 11 receives the data channel DCH_2 from the channel determination means 114 and the common control channel CCH9 from the reception means 113. Then, the transmission means 112 of the mobile terminal 11 generates the control information frame CTLF5 including the data channel DCH_2, and accesses the generated control information frame CTLF5 in the slot (= UL2) of the time frame TF2 using the common control channel CCH9. Send to point 1.

  The receiving means 103 of the access point 1 detects the arrival of a frame via the antenna 101, receives the control information frame CTLF5 through the common control channel CCH9, and outputs the received control information frame CTLF5 to the transmitting means 102.

  Then, the transmission means 102 of the access point 1 detects the data channel DCH_2 included in the control information frame CTLF5 received from the reception means 103, and the data channel used by the mobile terminal 11 for data frame communication is the data channel DCH_2. Detect that.

  As a result, the data channel DCH_2 is shared between the access point 1 and the mobile terminal 11.

  Thereafter, the access point 1 and the mobile terminal 11 select an unused channel during data frame transmission from the data channel DCH_2 by carrier sense, and transmit / receive the data frame DTF2 to / from each other in a time division manner using the selected channel. To do.

  Even in the time frame TF2, the reception unit 113 of the mobile terminal 11 detects the arrival of a frame in the frequency band (= 2402 to 2481 MHz) of the common control channels CCH1 to CCH16 via the antenna 111. As a result, the control information frame When not only the CTLF 5 but also the control information frame CTLF 6 from the access point 2 belonging to another cell C 2 is received, the control information frame CTLF 5 and the control information frame CTLF 6 are output to the channel determining means 114.

  Then, the channel determination unit 114 of the mobile terminal 11 receives from the transmission unit 112 the usage status of the channels CH1 to CH80 included in the control information frame CTLF5, the usage status of the channels CH1 to CH80 included in the control information frame CTLF6, and Based on the usage status of channels CH1 to CH80, data channel DCH_2 is determined by the method described above.

  As a result, the data channel DCH_2 can be determined from an unused channel in the cell C2 adjacent to the cell C1, and interference between the cells C1 and C2 can be avoided even in the time frame TF2.

  On the other hand, if the common control channel CCH9 is in use as a result of carrier sense on the common control channel CCH9 in the sensing period 2, the transmission means 102 of the access point 1 stops transmission of the control information frame CTLF in the time frame TF2. .

  Thereafter, the access point 1 repeatedly executes the above-described operation to change the common control channel CCH according to the hopping pattern (see FIG. 7) for each time frame TF, and uses the changed common control channel CCH to change the channel CH1. Control information frame CTLF including the use status of CH80 is transmitted to mobile terminal 11 in a time division manner. Then, the mobile terminal 11 determines the data channel DCH by the method described above and transmits it to the access point 1 for each time frame TF. Thereby, the access point 1 and the mobile terminal 11 share the data channel DCH for each time frame TF.

  The access points 2 to i and the mobile terminals 12 to 1 i also share the data channel DCH by the same method as the access point 1 and the mobile terminal 11.

  According to the above-described method, the frequency channel to be used is determined in an autonomous and distributed manner in each of the cells C1 to Ci prior to the transmission of the data frame, and the information is transmitted and received on the common control channel (transmission / reception nodes (access points 1 to i and mobile points)). Exchanged between terminals 11-1i).

[Determination of data channel between adjacent access points]
Cell C1 is adjacent to cells C2 and C3. In this case, the access point 1 that manages the cell C1 may be turned on later than the access point 2 that manages the cell C2.

  In such a case, the access point 2 shares a data channel with the mobile terminal 12 by the method described above, and transmits / receives a data frame to / from the mobile terminal 12 using the shared data channel. .

  As a result, it is difficult for the access point 1 to select a data channel while avoiding a collision with the data channel used by the access point 2 for transmitting and receiving data frames.

  Therefore, a method will be described in which the access point 1 that is turned on later than the other access point 2 determines the data channel.

  The access point 1 periodically selects a common control channel by the above-described method, and periodically transmits a control information frame including data channel selection information using the selected common control channel.

  The access point 2 also periodically selects a common control channel by the above-described method, and periodically transmits a control frame including data channel selection information using the selected common control channel.

  Then, for example, the access point 1 transmits a control information frame CTLF7 including the data channel selection information DCSI1 using the common control channel CCH1 in the time frame TF1. Further, the access point 2 transmits a control information frame CTLF8 including the data channel selection information DCSI2 using the common control channel CCH2 in the time frame TF1, for example.

  FIG. 9 is a diagram illustrating an example of data channel selection information. In FIG. 9, it is assumed that channels CH7 to CH80 are all in use.

  Referring to FIG. 9, access point 1 transmits control information frame CTLF7 including data channel selection information DCSI1-1 (a kind of data channel selection information DCSI1) using common control channel CCH1, and access point 2 A control information frame CTLF8 including data channel selection information DCSI2-1 (a kind of data channel selection information DCSI2) is transmitted using the common control channel CCH2.

  Then, the receiving means 103 of the access point 1 detects the arrival of frames on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF8 on the common control channel CCH2. Thereafter, the receiving means 103 of the access point 1 outputs the received control information frame CTLF8 to the channel determining means 104, and outputs the control information frame CTLF8 and the common control channel CCH2 to the transmitting means 102.

  The channel determination means 104 of the access point 1 receives the control information frame CTLF8 and extracts data channel selection information DCSI2-1 (see FIG. 9B) included in the received control information frame CTLF8.

  Further, the channel determination means 104 of the access point 1 receives the data channel selection information DCSI1-1 (see (a) of FIG. 9) from the transmission means 102.

  Then, the channel determination means 104 of the access point 1 determines unused channels CH2, CH4, and CH5 as overlapping data channels DDC based on the data channel selection information DCSI1-1 and DCSI2-1.

  Then, the channel determination means 104 of the access point 1 determines the release request data channel RDDC (= CH5, for example) that requests release from among the overlapping data channels DDC. Thereafter, the channel determination unit 104 of the access point 1 outputs the determined release request data channel RDDC (= CH5) to the transmission unit 102.

  Thus, the access point 1 determines the channels CH2, CH4, and CH5 that the access points 1 and 2 are planning to use as overlapping data channels DDC, and the determined overlapping data channel DDC (= CH2, CH2). By determining the release request data channel RDDC (= CH5) from among CH4 and CH5), the data channels used for data communication by the access points 1 and 2 can be set to different channels, and between the cells C1 and C2. Collisions can be avoided.

  The transmission means 102 of the access point 1 receives the common control channel CCH2 from the reception means 103 and receives the release request data channel RDDC (= CH5) from the channel determination means 104.

  Then, the transmission means 102 of the access point 1 generates a control information frame CTLF9 including the release request data channel RDDC (= CH5), and transmits the generated control information frame CTLF9 to the access point 2 using the common control channel CCH2. To do. That is, the access point 1 transmits the control information frame CTLF 9 to the access point 2 as a mobile terminal of the access point 2.

  The receiving means 103 of the access point 2 detects the arrival of a frame on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF9 on the common control channel CCH2. Then, the receiving means 103 of the access point 2 outputs the received control information frame CTLF9 to the channel determining means 104.

  The channel determination means 104 of the access point 2 receives the control information frame CTLF9 and extracts the release request data channel RDDC (= CH5) included in the received control information frame CTLF9.

  Then, the channel determination unit 104 of the access point 2 determines the data channel to be released based on the data channel selection information DCSI2-1 received from the transmission unit 102. More specifically, the channel determination means 104 of the access point 2 indicates that the release request data channel RDDC (= CH5) is included in the channels CH2, CH4, and CH5 that are not used in the data channel selection information DCSI2-1. Confirm and determine channel CH5 as the data channel to be released.

  Thereafter, the channel determination means 104 of the access point 2 deletes the channel CH5 from the data channel selection information DCSI2-1 to create the data channel selection information DCSI2-2 (see (c) of FIG. 9), and sets the channel CH5. The data is output to the transmission means 102.

  Thus, by deleting channel CH5 from data channel selection information DCSI2-1, it is possible to reliably set the data channels used by access points 1 and 2 for data communication to mutually different channels. This is because the access point 2 determines a data channel used for transmission / reception of a data frame with the mobile terminal 12 based on the data channel selection information DCSI2-2 from which the channel CH5 is deleted.

  The transmission means 102 of the access point 2 receives the data channel RDC (= CH5) to be released from the channel determination means 104. Then, the transmission means 102 of the access point 2 generates a control information frame CTLF10 including the received data channel RDC (= CH5) and receives the generated control information frame CTLF10 using the common control channel CCH2. Send to 1.

  The receiving means 103 of the access point 1 detects the arrival of a frame on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF10 on the common control channel CCH2. Then, the receiving means 103 of the access point 1 outputs the control information frame CTLF10 to the transmitting means 102. That is, the access point 1 receives the control information frame CTLF 10 from the access point 2 as a mobile terminal of the access point 2.

  The transmission means 102 of the access point 1 receives the control information frame CTLF10 and extracts the released data channel RDC (= CH5) from the received control information frame CTLF10. Further, the transmission means 102 of the access point 1 extracts the data channel selection information DCSI2-1 from the control information frame CTLF8.

  Then, the transmission means 102 of the access point 1 detects the channels CH2, CH4, CH5 that the access point 2 plans to use based on the data channel selection information DCSI2-1, and detects the detected channels CH2, CH4, CH4. Delete CH5 from the data channel selection information DCSI1-1. Thereafter, the transmission means 102 of the access point 1 adds the released data channel RDC (= CH5) to the data channel selection information DCSI1-1 and adds the data channel selection information DCSI1-2 (see (d) of FIG. 9). create. In this case, the transmission means 102 of the access point 1 adds the released data channel RDC (= CH5) to the data channel selection information DCSI1-1 as a channel in use.

  Note that the access point 1 deletes the channels CH2, CH4, and CH5 that the access point 2 intends to use from the data channel selection information DCSI1-1, so that the access points 1 and 2 use the data channel for data communication. It can be ensured that different channels are set. The access point 1 determines a data channel for transmitting / receiving a data frame to / from the mobile terminal 11 based on the data channel selection information DCSI1-2. In the data channel selection information DCSI1-2, the channels CH2 and CH4 This is because the channel CH5 is deleted in the data channel selection information DCSI2-2.

  In this way, when the priority is low due to a reason such as being turned on later than the access point 2, the access point 1 transmits the release request data channel RDDC to the access point 2 as a mobile terminal of the access point 2, The access point 2 adjusts so that the access point 1 can use a part of the channels CH2, CH4, and CH5 that it plans to use.

  Accordingly, the access point 1 can use the data channel, and the throughput of data transmission in the cell C1 can be improved.

  When the priority order of the access points 2 to i other than the access point 1 is lower than that of the other access points, the data channel used for data communication is acquired by the above-described method.

  FIG. 10 is a flowchart for explaining operations of an access point and a mobile terminal belonging to one cell of the wireless communication system 100.

  In addition, in FIG. 10, operation | movement of the access point 1 and the mobile terminal 11 which belong to the cell C1 is demonstrated.

  When a series of operations is started, the selection means 105 of the access point 1 selects the initial common control channel CCH_ini by the method described above, and sets the selected common control channel CCH_ini as the common control channel CCH (step S1).

  Then, the access point 1 sets m = 1 (step S2), and outputs the common control channel CCH to the transmission means 102. Thereafter, the transmission means 102 of the access point 1 performs carrier sense on the common control channel CCH based on the received signal strength information received from the reception means 103 during the sensing period of the time frame TF (m) (step S3). It is determined whether or not the channel CCH is in use (step S4).

  When it is determined in step S4 that the common control channel CCH is not in use, the transmission means 102 of the access point 1 uses the three slots (= DL1, UL1; DL2, UL2; DL3, DL) of the time frame TF (m). One arbitrary slot is selected from (UL3) (step S5).

  Thereafter, the transmission means 102 of the access point 1 generates a control information frame CTLF1 including a map indicating the usage status of the channels CH1 to CH80 by the method described above based on the carrier sense result on the channels CH1 to CH80 (step S1). S6).

  Then, the transmission means 102 of the access point 1 transmits the control information frame CTLF1 to the mobile terminal 11 using the common control channel CCH in the selected slot in the time frame TF (m) (step S7).

  Then, the receiving means 113 of the mobile terminal 11 detects the arrival of the frame on the channels CH1 to CH80, and receives the control information frame CTLF1 on the common control channel CCH (step S8).

  Then, the receiving means 113 of the mobile terminal 11 outputs the control information frame CTLF1 to the channel determining means 114 and outputs the common control channel CCH when the control information frame CTLF1 is received to the transmitting means 112.

  Thereafter, the channel determination means 114 of the mobile terminal 11 determines the data channel DCH based on the usage status of the channels CH1 to CH80 extracted from the control information frame CTLF1 and the usage status of the channels CH1 to CH80 observed by the transmission means 112. The determined data channel DCH is output to the transmission means 112 (step S9).

  The transmission means 112 of the mobile terminal 11 receives the data channel DCH from the channel determination means 114 and receives the common control channel CCH from the reception means 113. Then, the transmission means 112 of the mobile terminal 11 generates a control information frame CTLF2 including the data channel DCH (step S10), and selects a slot having the same number as the access point 1 (step S11). For example, if the access point 1 has selected a slot consisting of DL1, the transmission means 112 of the mobile terminal 11 selects a slot consisting of UL1. Since the access points 1 to i and the mobile terminals 11 to 1i are synchronized, the transmission unit 112 of the mobile terminal 11 receives the timing at which the reception unit 113 receives the control information frame CTLF1 (that is, the common control channel CCH ) From the receiving means 113), the slot selected by the access point 1 can be detected.

  After step S11, the transmission means 112 of the mobile terminal 11 transmits the control information frame CTLF2 to the access point 1 using the common control channel CCH in the selected slot (step S12).

  Then, the receiving means 103 of the access point 1 detects the arrival of the frame on the channels CH1 to CH80, receives the control information frame CTLF2 on the common control channel CCH (step S13), and transmits the received control information frame CTLF2 To 102.

  Thereafter, the transmission means 102 of the access point 1 receives the control information frame CTLF2 from the reception means 103, and detects the data channel DCH from the received control information frame CTLF2 (step S14). As a result, the data channel DCH is shared between the access point 1 and the mobile terminal 11.

  Then, the access point 1 and the mobile terminal 11 perform carrier sense on the data channel DCH, and if there is an unused channel in the data channel DCH, generate a data frame and use the unused channel to generate the data frame. Transmission and reception are performed in a time division manner (step S15).

  If all the data channels DCH are in use, the access point 1 and the mobile terminal 11 stop transmitting data frames.

  On the other hand, when it is determined in step S4 that the common control channel CCH is in use, the transmission means 102 of the access point 1 stops transmission of the control information frame CTLF (step S16).

  After step S15 or step S16, the access point 1 sets m = m + 1 (step S17), changes the common control channel according to the hopping pattern in the time frame TF (m), and changes the common control channel CCH_hop after the change. Is set to the common control channel CCH (step S18).

  Thereafter, the series of operations returns to Step S3, and Steps S3 to S18 described above are repeatedly executed.

  When step S5 is executed after the second time, the transmission means 102 of the access point 1 increments the slot number selected last time by one, selects a slot, selects a slot consisting of DL3, and then selects a slot. When selecting, the slot consisting of DL1 is selected.

  In this way, by selecting one slot from the three slots and transmitting the control information frame CTLF, access points using the same common control channel CCH can transmit the control information frame CTLF in a time division manner.

  As described above, in the embodiment of the present invention, the common control channel CCH is changed according to the hopping pattern in units of time frames, and the control information frame CTLF is transmitted and received in a time division manner, so that collision between 48 cells at the maximum is avoided. Thus, the data channel selection information indicating the data channel used for data frame communication can be exchanged, and the data channel selection information can be shared between the access point 1 and the mobile terminal 11.

  In addition, since the map indicating all the usage states of the channels CH1 to CH80 is included in the control information frame CTLF and transmitted from the access point to the mobile terminal in units of time frames (every 5 ms), both the frequency direction and the time direction It is possible to effectively use free frequency resources that change from time to time.

  The operations of the access points 2 to i and the mobile terminals 12 to 1i included in the cells C2 to Ci are also executed according to the flowchart shown in FIG.

  FIG. 11 is a flowchart for explaining determination of a data channel between access points. In FIG. 11, the determination of the data channel between the access points 1 and 2 will be described.

  Referring to FIG. 11, when a series of operations is started, access point 1 selects common control channel CCH1, and uses control information frame CTLF7 including data channel selection information DCSI1 using the selected common control channel CCH1. Is transmitted (step S21).

  Then, the access point 2 detects the arrival of the frame using the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF7 using the common control channel CCH1 (step S22).

  Thereafter, the access point 2 selects the common control channel CCH2, and transmits the control information frame CTLF8 including the data channel selection information DCSI2 using the selected common control channel CCH2 (step S23).

  Then, the access point 1 detects the arrival of frames on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF8 on the common control channel CCH2 (step S24). Thereafter, the access point 1 extracts the data channel selection information DCSI2 from the received control information frame CTLF8, and determines an overlapping data channel DDC based on the data channel selection information DCSI1 and DCSI2 (step S25).

  Subsequently, the access point 1 determines a release request data channel RDDC requesting release from among the overlapping data channels DDC (step S26). Then, the access point 1 generates a control information frame CTLF9 including the release request data channel RDDC, and transmits the generated control information frame CTLF9 to the access point 2 using the common control channel CCH2 (step S27). That is, the access point 1 transmits the control information frame CTLF 9 to the access point 2 as a mobile terminal of the access point 2.

  The access point 2 detects the arrival of frames on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF9 on the common control channel CCH2 (step S28). Then, the access point 2 determines the data channel RDC to be released by the method described above based on the release request data channel RDDC and the data channel selection information DCSI2 included in the received control information frame CTLF9 (step S29). ).

  Thereafter, the access point 2 deletes the data channel RDC to be released from the data channel selection information DCSI2 (step S30).

  Subsequently, the access point 2 generates a control information frame CTLF10 including the data channel RDC to be released, and transmits the generated control information frame CTLF10 to the access point 1 using the common control channel CCH2 (step S31).

  The access point 1 detects the arrival of frames on the channels CH1 to CH80 via the antenna 101, and receives the control information frame CTLF10 on the common control channel CCH2 (step S32). That is, the access point 1 receives the control information frame CTLF 10 from the access point 2 as a mobile terminal of the access point 2. Then, the access point 1 detects a channel scheduled to be used by the access point 2 based on the data channel selection information DCSI2, and deletes the detected channel from the data channel selection information DCSI1. Thereafter, the access point 1 adds the released data channel RDC to the data channel selection information DCSI1-1 (step S33). As a result, the series of operations ends.

  When the access point 1 acquires a data channel used for data communication, the access point 1 shares the data channel with the mobile terminal 11 according to the flowchart shown in FIG. 10 and transmits / receives a data frame to / from the mobile terminal 11.

  Note that, when the access points 2 to i other than the access point 1 determine the data channel with the adjacent access points, the access points 2 to i determine the data channel according to the flowchart shown in FIG.

  In this way, when the priority is low due to a reason such as being turned on later than the access point 2, the access point 1 transmits the release request data channel RDDC to the access point 2 as a mobile terminal of the access point 2, The access point 2 adjusts so that the access point 1 can use a part of the channel that it plans to use.

  Accordingly, the access point 1 can use the data channel, and the throughput of data transmission in the cell C1 can be improved.

  In the embodiment of the present invention, the access point 1 constitutes a “wireless device” or “first wireless device”, and the access point 2 constitutes a “second wireless device” or “other wireless device”. Is configured.

  In the embodiment of the present invention, the common control channel CCH1 constitutes a “first common control channel”, and the common control channel CCH2 constitutes a “second common control channel”.

  Further, the data channel selection information DCSI1 constitutes “first data channel selection information”, and the data channel selection information DCSI2 constitutes “second data channel selection information”.

  Furthermore, the fact that the access points 1 to i transmit / receive control information frames in units of time frames corresponds to the access points 1 to i periodically transmitting / receiving control information frames.

  Furthermore, transmission / reception of the control information frame in units of time frames by the mobile terminals 11 to 1i corresponds to that the mobile terminals 11 to 1i periodically transmit / receive the control information frame.

  The embodiment disclosed this time should be considered as illustrative in all points and not restrictive. The scope of the present invention is shown not by the above description of the embodiments but by the scope of claims for patent, and is intended to include meanings equivalent to the scope of claims for patent and all modifications within the scope.

  The present invention is applied to a radio apparatus that improves throughput in a cell. The present invention is also applied to a wireless communication system including a wireless device that improves throughput in a cell.

  1 to i access points, 11 to 1i mobile terminals, 100 wireless communication systems, 101 and 111 antennas, 102 and 112 transmission means, 103 and 113 reception means, 104 and 114 channel determination means, 105 selection means, 106 hopping table, 107 115 Synchronization establishing means.

Claims (6)

A wireless communication system that performs wireless communication in a wireless communication environment in which a plurality of cells, each managed by a single base station, and a plurality of different wireless systems are mixed,
A first common control channel is periodically selected by a frequency hopping method from a frequency band used by the plurality of radio systems, carrier sense is performed on the selected first common control channel, and the selected first When one common control channel is not used, first data channel selection information for selecting a data channel used for data communication is periodically transmitted using the selected first common control channel. A first wireless device;
A second cell adjacent to the first cell managed by the first wireless device is managed, and a second common control channel is periodically assigned from a frequency band used by the plurality of wireless systems by a frequency hopping method. Select the second common control channel, perform carrier sense on the selected second common control channel, and use the selected second common control channel when the selected second common control channel is unused. A second wireless device that periodically transmits second data channel selection information for selecting a data channel used for communication,
The first radio apparatus receives the second data channel selection information from the second radio apparatus using the second common control channel as necessary, and the received second data channel Based on the selection information and the first data channel selection information, an overlapping data channel is determined, and an opening request data channel for requesting the second wireless device to open is selected from the overlapping data channels. A wireless communication system that determines and transmits the determined release request data channel to the second wireless device using the second common control channel.   When the second radio apparatus receives the release request data channel from the first radio apparatus using the second common control channel, the second radio apparatus uses the first radio channel based on the second data channel selection information. A data channel to be released to the apparatus is determined, the data channel to be released is deleted from the second data channel selection information, and the data channel to be released is set to the first using the second common control channel. The wireless communication system according to claim 1, wherein the wireless communication system transmits to the wireless device.   When the first wireless device receives the released data channel from the second wireless device using the second common control channel, the first wireless device selects the data channel that the second wireless device is scheduled to use. The wireless communication system according to claim 1, wherein the first data channel selection information is deleted and the released data channel is added to the first data channel. A radio apparatus used in a radio communication system that performs radio communication in a radio communication environment in which a plurality of cells each managed by a single base station exist and a plurality of different radio systems coexist,
Selection means for periodically selecting a common control channel from a frequency band used by the plurality of wireless systems by a frequency hopping method;
Based on the received signal strength information in the frequency band, carrier sensing is performed on the first common control channel selected by the selection unit, and the selected first common control channel is unused. Transmission means for periodically transmitting first data channel selection information for selecting a data channel used for data communication using the first common control channel;
The received signal strength information on the first common control channel is generated by measuring the received signal strength in the frequency band, and the generated received signal strength information is output to the transmitting means, and the radio device manages the first Second data channel selection information used for data communication by another radio apparatus managing the second cell adjacent to one cell is transmitted from the other radio apparatus using the second common control channel as necessary. Receiving means for receiving;
Based on the first and second data channel selection information, an overlapping data channel is determined, and from among the overlapping data channels, an opening request data channel for requesting opening to the other radio apparatus is determined. Channel determining means for
The transmitting means further transmits the determined release request data channel to the other wireless device using the second common control channel.   When the receiving unit receives the release request data channel from the other radio apparatus using the first common control channel, the channel determination unit is configured to perform the other radio based on the first data channel selection information. Determining a data channel to be released to the device, deleting the data channel to be released from the first data channel selection information, and using the first common control channel to release the data channel to be released The wireless device according to claim 4, wherein the wireless device transmits to the wireless device.   When the receiving unit receives the released data channel from the other wireless device using the second common control channel, the transmitting unit transmits the data channel scheduled to be used by the other wireless device. The radio apparatus according to claim 4, wherein the radio apparatus is deleted from the first data channel selection information and the released data channel is added to the first data channel selection information.

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