JP5540245B2 - Wireless communication system, receiving station, and transmitting station - Google Patents

Description

  The present invention relates to a wireless communication system or the like that can effectively use wireless resources.

  With the development of information systems for the realization of ubiquitous networks, the spread and development of indoor and short-range personal wireless systems such as wireless LAN and RF-ID are progressing, and further demand for radio waves is expected in the future. . However, since frequency resources are limited and radio waves are tight in a band of 6 GHz or less suitable for mobile communication and wireless systems, it is difficult to assign a new frequency band.

  On the other hand, it is desirable that a self-operated indoor / short-range wireless system does not require a license, and is normally operated in an ISM (industry-science-medical) band such as 2.4 GHz. For this reason, with the increase in radio wave usage in the future, there are concerns about an increase in transmission delay due to shortage of radio channels, a decrease in transmission speed, and an increase in transmission errors due to interference. The ISM band is shared by various wireless systems. By checking the availability of a wireless channel having an arbitrary frequency and bandwidth by carrier sense, the wireless resources (frequency, time slot) are secured and used. For this reason, a lot of fragmented free radio resources, that is, a large number of “gaps” in the spectrum are left unnecessarily.

  In order to solve this problem, a concept of a dynamic spectrum access (DSA) system in which fragmented free spectrum is accumulated and used as one radio channel has been proposed (Non-Patent Document 1). In addition, as a spectrum control method suitable for coexistence with other systems that operate asynchronously and autonomously, spectrum division with band limitation that divides the spectrum of single carrier modulation into multiple bands and frequency-converts each to transmit Single carrier transmission systems have also been proposed (Non-Patent Documents 2 and 3). Further, in order to realize high-efficiency frequency sharing such as ISM band, a multiple access scheme using CSMA / CA, FDMA and TDMA in combination and its physical channel configuration have been proposed (Non-Patent Document 4).

  Further, FIG. 19 shows a downlink data transmission procedure in Non-Patent Document 4. In FIG. 19, the base station (AP) transmits call information (transmission start) to the mobile terminal (MS). And AP produces | generates channel selection information from a channel sensing result, and transmits to MS. The MS determines the data channel information from the channel sensing result and the description contents of all the channel selection information successfully received, and transmits it to the AP. The AP transmits data to the MS using only the frequency channel determined to be unused from the data channel information from the MS and the channel sensing result. When these procedures are repeated and the AP completes the transmission of all data, the transmission completion information is transmitted to the MS to complete the procedure.

  Next, the uplink data transmission procedure in Non-Patent Document 4 is shown in FIG. The procedure in which the AP generates channel selection information and the MS determines data channel information is the same as that in FIG.

  Furthermore, there has been a technique for providing a base station and a transmission method for efficiently transmitting a control channel to various terminals having different communicable bandwidths (Patent Document 1). Such a technique is based on channel state information reported from each communication terminal to a multicarrier base station that performs frequency scheduling in a frequency band including a plurality of resource blocks including one or more subcarriers. A frequency scheduler that determines scheduling information for allocating blocks to communication terminals with good channel conditions, a means for encoding and modulating a control channel for transmitting scheduling information, and a frequency for control channels and other channels according to the scheduling information This is achieved by including multiplexing means for multiplexing and means for transmitting the output signal of the multiplexing means in a multicarrier system.

JP 2007-336500 A (first page, FIG. 1 etc.)

Taro Maruma, Hitoshi Yano, Seiji Tsukamoto, Masazumi Kamiha, "Proposal of Dynamic Spectrum Access System for Highly Efficient Frequency Sharing in ISM Band," IEICE Technical Report, SR2008-97, pp.53-57, March 2009. Taro Maruma, Hitoshi Yano, Masazumi Kamiha, "Proposal of Bandwidth-Limited Spectrum Division Single Carrier Transmission System for Dynamic Spectrum Access in ISM Band," IEICE Technical Report, SR2009-2, pp.7-12, May 2009. Yasuo Suzuki, Makoto Taromaru, Hitoshi Yano, Masazumi Kamiha, “Basic Performance of Band-Limited Spectrum Division Single Carrier Transmission System for DSA,” IEICE Technical Report, RCS2009-81, pp.19-23, Aug. 2009. Hitoshi Yano, Hideyoshi Tsuji, Yasuo Suzuki, Seiji Tsukamoto, Makoto Taro, and Masazumi Kamiha, "Examination of Physical Channel Configuration of Dynamic Spectrum Access System for Highly Efficient Frequency Sharing in ISM Band," IEICE Technical Report, SR2008- 98, pp.59-64, March 2009.

  However, in the DSA system, it is necessary to determine the data transmission frequency from the channel sensing results of both transmitting and receiving nodes. Since the channel sensing result changes from moment to moment, the data transmission throughput decreases due to a time delay due to the exchange of channel sensing results.

  In addition, for example, in the procedure of Non-Patent Document 4, three channel sensing is required to send one slot of the data channel, so that the data transmission throughput is reduced.

  The wireless communication system of the first aspect of the invention is a wireless communication system in which a receiving station and a transmitting station communicate wirelessly, and the receiving station performs sensing from a predetermined frequency band and can receive one or more. Receivable frequency information acquisition unit for acquiring receivable frequency information that is frequency information of the receiver, and receivable frequency information for transmitting the receivable frequency information to the transmitting station using a frequency different from the frequency indicated by the receivable frequency information. A transmission unit, a data transmission frequency information receiving unit that receives data transmission frequency information indicating a frequency at which data is transmitted from a transmitting station, and a data receiving unit that receives data using the frequency indicated by the data transmission frequency information. The transmitting station performs sensing from a predetermined frequency band and acquires transmittable frequency information that is information of one or more frequencies that can be transmitted. Transmittable frequency information acquisition unit, receivable frequency information receiving unit that receives receivable frequency information from the receiving station, one or more receivable frequencies indicated by the receivable frequency information, and one or more transmissions indicated by the transmittable frequency information A data transmission frequency information acquisition unit that determines one or more frequencies for transmitting data from one or more frequencies that coincide with each other, and acquires data transmission frequency information that is frequency information; A data transmission frequency information transmitter that transmits data transmission frequency information to the receiving station using a frequency different from the frequency indicated by the transmittable frequency information, and transmits data to the receiving station using the frequency indicated by the data transmission frequency information. And a data transmission unit.

  With this configuration, in the dynamic spectrum access system, it is possible to prevent a reduction in data transmission throughput due to a time delay due to exchange of channel sensing results.

  In the wireless communication system according to the second aspect of the present invention, in contrast to the first aspect of the invention, the transmitting station further includes a maximum transmittable data rate storage unit that stores information on the maximum transmittable data rate, and the data The transmission frequency information acquisition unit includes one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information so as not to exceed the maximum transmittable data rate. The wireless communication system determines one or more frequencies for transmitting data from one or more matching frequencies, and acquires data transmission frequency information, which is frequency information.

  With this configuration, in the dynamic spectrum access system, it is possible to prevent a reduction in data transmission throughput due to a time delay due to exchange of channel sensing results.

  In the wireless communication system according to the third aspect of the present invention, with respect to any one of the first to second aspects, the receiving station includes a receivable maximum data rate storage unit storing information on a receivable maximum data rate; A receivable maximum data rate information transmitting unit that transmits information on the maximum receivable data rate to the transmitting station, and the transmitting station receives receivable maximum data rate information from the receiving station. It further includes a rate information receiver, and the data transmission frequency information acquisition unit can transmit with one or more receivable frequencies indicated by the receivable frequency information so as not to exceed the maximum transmittable data rate and the maximum receivable data rate. Among one or more transmittable frequencies indicated by the frequency information, one or more frequencies for transmitting data are determined from one or more coincident frequencies, and data that is frequency information is determined. A wireless communication system to obtain the transmit frequency information.

  With this configuration, in the dynamic spectrum access system, it is possible to prevent a reduction in data transmission throughput due to a time delay due to exchange of channel sensing results.

  Further, in the wireless communication system according to the fourth aspect of the present invention, with respect to any one of the first to third aspects, the receiving station uses the scheduled use frequency information that is information on the frequency that the base station is scheduled to use The wireless communication apparatus further includes a scheduled use frequency information receiving unit that receives from the base station, and the receivable frequency information acquisition unit matches one or more frequencies indicated by the scheduled use frequency information with one or more frequencies indicated by the frequency band. A wireless communication system that performs sensing from one or more frequencies to obtain receivable frequency information that is information of one or more receivable frequencies.

  With this configuration, the receiving station can narrow the range of the sensing frequency of the receiving station by grasping the frequency to be used by the base station, and as a result, the channel sensing process can be speeded up.

  In addition, in the radio communication system of the fifth invention, in contrast to any one of the first to fourth inventions, the transmitting station uses scheduled frequency information, which is information on a frequency that the base station plans to use, The wireless communication apparatus further includes a scheduled use frequency information receiving unit that receives from the base station, and the transmittable frequency information acquisition unit matches between one or more frequencies indicated by the scheduled use frequency information and one or more frequencies indicated by the frequency band. A wireless communication system that performs sensing from one or more frequencies to obtain transmittable frequency information that is information of one or more frequencies that can be transmitted.

  With this configuration, the transmitting station can grasp the frequency scheduled to be used by the base station, thereby narrowing the range of the sensing frequency of the transmitting station. As a result, the channel sensing process can be speeded up.

  Further, in the radio communication system according to the sixth aspect of the present invention, in contrast to any one of the first to fifth aspects, the data transmission frequency information transmitting unit and the data transmitting unit simultaneously transmit the data transmission frequency information and data to the receiving station. It is the radio | wireless communications system transmitted to.

  With this configuration, the data transmission frequency information and the data can be transmitted to the receiving station at the same time. As a result, the data transmission waiting time can be shortened and the data transmission throughput can be increased.

  Further, the wireless communication system of the seventh aspect of the invention is different from the first to sixth aspects of the invention in that the frequency is different from the frequency indicated by the receivable frequency information or the frequency different from the frequency indicated by the transmittable frequency information. Is a radio communication system which is a frequency of one common control channel among one or more predetermined common control channels.

  According to the wireless communication system of the present invention, it is possible to prevent the data transmission throughput from being lowered in the dynamic spectrum access system.

Block diagram of radio communication system according to Embodiment 1 Flow chart explaining the operation of the receiving station Flow chart explaining operation of the transmitting station Conceptual diagram of the wireless communication system Diagram showing the configuration of the channel Diagram showing the configuration of the control channel Diagram showing the specifications of the control channel Diagram showing the configuration of the data channel Diagram showing the specifications of the data channel Diagram showing the control channel and data channel Diagram showing the configuration of the control channel Diagram showing the structure of the control information Diagram showing the structure of the call information The figure which shows the structure of the control information Diagram showing the configuration of the data channel The figure which shows the downlink data transmission procedure in the same radio | wireless communications system The figure which shows the uplink data transmission procedure in the radio | wireless communications system The figure which shows the same AP relay transmission procedure The figure which shows the downlink data transmission procedure in the same conventional radio | wireless communications system The figure which shows the uplink data transmission procedure in the conventional radio | wireless communications system

Hereinafter, embodiments of a wireless communication system and the like will be described with reference to the drawings. In addition, since the component which attached | subjected the same code | symbol in embodiment performs the same operation | movement, description may be abbreviate | omitted again.
(Embodiment 1)

  In the present embodiment, a radio communication system in which a receiving station determines a frequency of data transmission from a frequency that can be received by the receiving station, and the transmitting station determines a frequency of data transmission from the frequency that can be transmitted by the transmitting station. explain.

  In this embodiment, the transmitting station determines the frequency of one or more channels so as not to exceed the maximum transmittable data rate of the transmitting station. Further, the transmitting station determines the frequency of one or more channels so as not to exceed the maximum receivable data rate of the receiving station.

  In the present embodiment, a radio communication system in which the receiving station and the transmitting station narrow down the sensing frequency range by grasping the frequency that the base station plans to use will be described.

  Furthermore, in the present embodiment, a description will be given of a radio communication system in which a transmitting station transmits information on a frequency for transmitting data and data to the receiving station at the same time.

  FIG. 1 is a block diagram of a wireless communication system 1 in the present embodiment. The wireless communication system 1 includes a receiving station 11 and a transmitting station 12. For example, the receiving station 11 is a mobile terminal, and the transmitting station 12 is a base station (AP: Access Point). For example, the receiving station 11 is a base station and the transmitting station 12 is a mobile terminal. Further, the receiving station 11 and the transmitting station 12 may be both base stations or mobile terminals. Hereinafter, the base station is also referred to as an access point as appropriate.

  The receiving station 11 includes a receivable maximum data rate storage unit 111, a receivable maximum data rate information transmitting unit 112, a receiving station side scheduled use frequency information receiving unit 113, a receivable frequency information acquiring unit 114, and a receivable frequency information transmitting unit 115. A data transmission frequency information receiving unit 116 and a data receiving unit 117. The antenna 110 of the receiving station 11 receives the control information frame or data frame and outputs the received control information frame or data frame to the receiving means of the receiving station 11. The antenna 110 of the receiving station 11 receives a control information frame or data frame from the transmitting means, and transmits the received control information frame or data frame to the transmitting station 12. The receiving means of the receiving station 11 includes a receiving station side scheduled use frequency information receiving unit 113, a data transmission frequency information receiving unit 116, and a data receiving unit 117. The transmission means of the receiving station 11 includes a receivable maximum data rate information transmitting unit 112 and a receivable frequency information transmitting unit 115.

  The transmitting station 12 includes a transmittable maximum data rate storage unit 121, a receivable maximum data rate information receiving unit 122, a transmitting station side scheduled use frequency information receiving unit 123, a transmittable frequency information acquiring unit 124, and a receivable frequency information receiving unit 125. A data transmission frequency information acquisition unit 126, a data transmission frequency information transmission unit 127, and a data transmission unit 128. The antenna 120 of the transmitting station 12 receives the control information frame or data frame and outputs the received control information frame or data frame to the receiving means of the transmitting station 12. The antenna 120 of the transmitting station 12 receives a control information frame or data frame from the transmitting means, and transmits the received control information frame or data frame to the receiving station 11. The receiving means of the transmitting station 12 includes a receivable maximum data rate information receiving unit 122, a transmitting station side scheduled use frequency information receiving unit 123, and a receivable frequency information receiving unit 125. The transmission means of the transmission station 12 includes a data transmission frequency information transmission unit 127 and a data transmission unit 128.

  The receivable maximum data rate storage unit 111 stores information on the maximum receivable data rate. The maximum receivable data rate is the maximum data rate that the receiving station 11 can receive. The maximum receivable data rate in the receivable maximum data rate storage unit 111 is preferably dynamically acquired by means not shown, but may be stored in advance. The maximum receivable data rate is information due to hardware limitations. The receivable maximum data rate storage unit 111 is preferably a non-volatile recording medium, but can also be realized by a volatile recording medium. The process of storing the maximum receivable data rate information in the maximum receivable data rate storage unit 111 is not limited.

  The receivable maximum data rate information transmission unit 112 transmits information on the maximum receivable data rate stored in the receivable maximum data rate storage unit 111 to the transmission station 12.

  When the receiving station 11 is a mobile terminal, the receiving station side scheduled use frequency information receiving unit 113 receives the scheduled use frequency information, which is information on the frequency scheduled to be used by the base station in the cell to which the receiving station 11 belongs, Receive from. Here, the base station is usually the transmitting station 12. In addition, when the receiving station 11 is a base station, the receiving station side scheduled use frequency information receiving unit 113 converts the scheduled use frequency information, which is information on the frequency scheduled to be used by another base station, to another base station. You may receive from.

  The receivable frequency information acquisition unit 114 performs sensing from a predetermined frequency band, and acquires receivable frequency information that is information of one or more receivable frequencies. The receivable frequency information acquisition unit 114 knows the predetermined frequency band. The predetermined frequency band is, for example, a frequency band of 2402 MHz to 2481 MHz. However, the frequency band does not matter.

  When the receiving station 11 is a mobile terminal, the receivable frequency information acquisition unit 114 senses a frequency at which the frequency indicated by the scheduled use frequency information matches a predetermined frequency band, and receives information on one or more frequencies that can be received. It is preferable to acquire the receivable frequency information. When the receiving station 11 is a base station, the receivable frequency information acquisition unit 114 performs sensing from a predetermined frequency band except for the frequency indicated by the scheduled use frequency information, and can receive one or more frequencies. It is preferable to acquire the receivable frequency information which is information of the above. The scheduled use frequency information is information received by the receiving station side scheduled use frequency information receiving unit 113.

  The receivable frequency information transmission unit 115 transmits receivable frequency information to the transmission station 12 using a frequency different from the frequency indicated by the receivable frequency information. The frequency different from the frequency indicated by the receivable frequency information is a frequency of one channel among one or more predetermined control channels. The control channel is a channel that transmits a communication control signal.

  The data transmission frequency information receiving unit 116 receives data transmission frequency information indicating a frequency for transmitting data from the transmitting station 12.

  The data receiving unit 117 receives data using the frequency indicated by the data transmission frequency information indicated by the data transmission frequency information receiving unit 116. The data receiving unit 117 receives data from the transmitting station 12.

  The maximum transmittable data rate storage unit 121 stores information on the maximum transmittable data rate. The maximum data rate that can be transmitted is the maximum data rate that the transmitting station 12 can transmit. The maximum transmittable data rate stored in the transmittable maximum data rate storage unit 121 is preferably dynamically acquired by means not shown, but may be stored in advance. The maximum data rate that can be transmitted is information due to hardware restrictions. The transmittable maximum data rate storage unit 121 is preferably a non-volatile recording medium, but can also be realized by a volatile recording medium. The process of storing the maximum transmittable data rate information in the transmittable maximum data rate storage unit 121 does not matter.

  The receivable maximum data rate information receiving unit 122 receives information on the maximum receivable data rate from the receiving station 11.

  When the transmitting station 12 is a base station, the transmitting station-side scheduled use frequency information receiving unit 123 receives scheduled use frequency information that is information on frequencies that other base stations plan to use from other base stations. You may do it. When the transmitting station 12 is a mobile terminal, the transmitting station side scheduled use frequency information receiving unit 123 normally uses the scheduled use frequency information, which is information on the frequency scheduled to be used by the base station in the cell to which the transmitting station 12 belongs, Receive from the base station.

  The transmittable frequency information acquisition unit 124 performs sensing from a predetermined frequency band, and acquires transmittable frequency information that is information of one or more frequencies that can be transmitted. The predetermined frequency band is known by the transmittable frequency information acquisition unit 124. The predetermined frequency band is, for example, a frequency band of 2402 MHz to 2481 MHz. The predetermined frequency band is not limited.

  When the transmitting station 12 is a base station, the transmittable frequency information acquisition unit 124 performs sensing from a predetermined frequency band except for the frequency indicated by the scheduled use frequency information, and transmits information on one or more frequencies that can be transmitted. It is preferable to acquire the transmittable frequency information. Further, when the transmitting station 12 is a mobile terminal, the transmittable frequency information acquisition unit 124 senses a frequency in which the frequency indicated by the use-scheduled frequency information matches a predetermined frequency band, and receives one or more receivable frequencies. It is preferable to obtain receivable frequency information that is frequency information. The scheduled use frequency information is information received by the transmission station side scheduled use frequency information receiving unit 123.

  The receivable frequency information receiving unit 125 receives receivable frequency information from the receiving station 11.

  The data transmission frequency information acquisition unit 126 selects one or more frequencies that match between one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information. Then, one or more frequencies for transmitting data are determined, and data transmission frequency information, which is frequency information, is acquired.

  The data transmission frequency information acquisition unit 126 includes one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information so as not to exceed the maximum transmittable data rate. Of these, it is preferable to determine one or more frequencies at which data is transmitted from one or more matching frequencies and acquire data transmission frequency information, which is frequency information.

  Further, the data transmission frequency information acquisition unit 126 includes one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information so as not to exceed the maximum receivable data rate. Of these, it is preferable to determine one or more frequencies at which data is transmitted from one or more matching frequencies and acquire data transmission frequency information, which is frequency information.

  The data transmission frequency information transmitting unit 127 transmits the data transmission frequency information to the receiving station 11 using a frequency different from the frequency indicated by the transmittable frequency information. The frequency different from the frequency indicated by the transmittable frequency information is a frequency of one channel among one or more predetermined control channels.

  The data transmission unit 128 transmits data to the receiving station 11 using the frequency indicated by the data transmission frequency information.

  It is preferable that the data transmission frequency information transmission unit 127 and the data transmission unit 128 transmit the data transmission frequency information and the data to the receiving station 11 at the same time.

  Further, a frequency different from the frequency indicated by the receivable frequency information, a frequency different from the frequency indicated by the transmittable frequency information, or a frequency different from the frequency indicated by the receivable frequency information and the frequency indicated by the transmittable frequency information. Preferably, the different frequency is a frequency of one common control channel among one or more predetermined common control channels.

  Next, the operation of the wireless communication system 1 will be described. First, the operation of the receiving station 11 will be described using the flowchart of FIG.

  (Step S201) The receiving station side scheduled use frequency information receiving unit 113 has received from the base station the scheduled use frequency information that is information on the frequency scheduled to be used by the base station in the cell to which the receiving station belongs. Determine whether. If the scheduled use frequency information is received, the process goes to step S202, and if not, the process goes to step S208. In addition, when not receiving use frequency information, you may perform to step S202.

  (Step S202) The receivable frequency information acquisition unit 114 senses a frequency that matches the frequency indicated by the scheduled use frequency information received in Step S201 and a predetermined frequency band.

  (Step S203) The receivable frequency information acquisition unit 114 acquires receivable frequency information that is information of one or more frequencies that can be received as a result of sensing in step S202. The receivable frequency information and the transmittable frequency information are also referred to as sensing results as appropriate.

  (Step S204) The receivable frequency information transmitting unit 115 transmits the receivable frequency information acquired in step S203 to the transmitting station 12 using a frequency different from the frequency indicated by the receivable frequency information.

  (Step S <b> 205) The receiving means (the data transmission frequency information receiving unit 116 and the data receiving unit 117) determines whether data transmission frequency information or data has been received from the transmitting station 12. If data transmission frequency information or data is received, the process proceeds to step S206, and if not received, the process returns to step S205. The data receiving unit 117 acquires data of the frequency indicated by the data transmission frequency information received by the data transmission frequency information receiving unit 116.

  (Step S206) The receiving means at least temporarily stores the data transmission frequency information and data received in Step S205 in the buffer.

  (Step S207) The data receiving unit 117 demodulates data at a frequency indicated by the data transmission frequency information stored in the buffer. The process returns to step S201.

  (Step S <b> 208) The receivable maximum data rate information transmission unit 112 determines whether it is time to transmit information about the maximum receivable data rate to the transmitting station 12. If it is time to transmit, the process goes to step S209, and if not, the process returns to step S201. Note that the receivable maximum data rate information transmission unit 112 may always determine that it is the timing to transmit information about the maximum receivable data rate, or a predetermined time or more has elapsed since the previous transmission. For example, when a certain condition is satisfied, it may be determined that it is time to transmit information on the maximum receivable data rate.

  (Step S209) The receivable maximum data rate information transmission unit 112 reads information on the maximum receivable data rate stored in the maximum receivable data rate storage unit 111, and transmits the information on the maximum receivable data rate to the transmission station 12. Send to.

  In the flowchart of FIG. 2, the process is terminated by powering off or a process termination interrupt.

  Next, the operation of the transmitting station 12 will be described using the flowchart of FIG.

  (Step S301) The transmission station side scheduled use frequency information receiving unit 123 determines whether or not the scheduled use frequency information, which is information on the frequency scheduled to be used by another base station, has been received from another base station. To do. If the scheduled use frequency information is received, the process goes to step S302, and if not received, the process goes to step S308.

  (Step S302) The transmittable frequency information acquisition unit 124 performs sensing from a predetermined frequency band except for the frequency indicated by the scheduled use frequency information received in Step S301.

  (Step S303) As a result of sensing in step S302, the transmittable frequency information acquisition unit 124 acquires transmittable frequency information that is information of one or more frequencies that can be transmitted.

  (Step S304) The receivable frequency information receiving unit 125 determines whether or not the receivable frequency information is received from the receiving station 11. If receivable frequency information is received, it will go to step S305, and if not received, it will return to step S304.

  (Step S305) The data transmission frequency information acquisition unit 126 reads the maximum transmittable data rate from the transmittable maximum data rate storage unit 121.

  (Step S306) The data transmission frequency information acquisition unit 126 includes one or more receivable frequencies indicated by the receivable frequency information received in step S304 and one or more transmissions indicated by the transmittable frequency information acquired in step S303. Among the possible frequencies, one or more frequencies for transmitting data are determined from one or more coincident frequencies, and data transmission frequency information, which is frequency information, is acquired. In this case, the data transmission frequency information acquisition unit 126 acquires the data transmission frequency information so as not to exceed the maximum transmittable data rate read in step S305. In such a case, the data transmission frequency information acquisition unit 126 acquires the data transmission frequency information so as not to exceed the maximum receivable data rate received in step S308.

  (Step S307) The data transmission frequency information transmitting unit 127 transmits the data transmission frequency information acquired in step S306 to the receiving station 11 using a frequency different from the frequency indicated by the transmittable frequency information. In addition, the data transmission unit 128 transmits data to the receiving station 11 using the frequency indicated by the data transmission frequency information. That is, the data transmission frequency information and the data are transmitted to the receiving station 11 at the same time. The data transmission frequency information is transmitted using the control channel, and the data is transmitted using the data channel. In addition, the data transmission unit 128 acquires, for example, data to be transmitted from a predetermined buffer. The process returns to step S301.

  (Step S308) The receivable maximum data rate information receiving unit 122 determines whether information about the maximum receivable data rate is received from the receiving station 11. If information on the maximum receivable data rate is received, the process goes to step S309, and if not received, the process goes to step S301.

  (Step S309) The receivable maximum data rate information receiving unit 122 temporarily stores the maximum receivable data rate information received in step S308 in a buffer. The process returns to step S301.

  In the flowchart of FIG. 3, the process ends when the power is turned off or the process is terminated.

  In the flowcharts of FIGS. 2 and 3, sensing is usually performed immediately before transmission of the control channel.

  Hereinafter, a specific operation of the wireless communication system 1 in the present embodiment will be described. A conceptual diagram of the wireless communication system 1 is shown in FIG. 4, the wireless communication system 1 includes access points (AP: Access Point) A1 to Ai (i is an integer of 2 or more) and mobile terminals (MS: Mobile Station) M1 to Mi.

  Access point A1 and mobile terminal M1 are arranged in cell C1. Access point A2 and mobile terminal M2 are arranged in cell C2. Hereinafter, similarly, the access point Ai and the mobile terminal Mi are arranged in the cell Ci.

  Although not shown in FIG. 4, for example, there are an access point and a mobile terminal that perform wireless communication by a CSMA / CA (Carrier Sense Multiple Access Collision Aviation) method, and FH-SS (Frequency-Hopping Spread). There are also access points and mobile terminals that perform wireless communication by the (Spectrum) method.

  Therefore, the access points A1 to Ai and the mobile terminals M1 to Mi change with time in a wireless communication environment in which a plurality of wireless systems such as CSMA / CA wireless systems and FH-SS wireless systems coexist and coexist. The usage status of the frequency resource is accurately grasped, an appropriate transmission frequency (frequency channel) is selected, and data is transmitted in each of the cells C1 to Ci. That is, the access points A1 to Ai and the mobile terminals M1 to Mi transmit data within the cells C1 to Ci by the DSA system.

  In FIG. 4, only one access point and one mobile terminal are shown in each of the cells C1 to Ci. Usually, each cell C1 to Ci has a plurality of mobile terminals. Exists.

  In this specific example, the mobile terminals M1 to Mi are mainly described as the receiving station 11, and the access points A1 to Ai are described as the transmitting station 12.

  FIG. 5 is an example of a channel configuration diagram in this embodiment. In the embodiment of the present invention, it is assumed that 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 physical channel includes a control channel (also referred to as a common control channel) that transmits a communication control signal and a data channel that transmits a data signal.

  CCH1 to CCH16 are 16 channels with channel numbers ending with “1” or “6”, and are control channels. These frequencies are the same as the transmission frequencies used by the IEEE 802.11 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 control channels CCH1 to CCH16 are used preferentially for transmission of communication control signals (also referred to as control information frames), and the remaining 64 channels. These channels are used for transmitting data signals (also referred to as data frames).

  A control channel that is not used for transmission of a communication control signal can be temporarily used for transmission of a data signal.

  The configuration of the control channel is shown in FIG. Further, the specification of the control channel is shown in FIG. A line from the base station (AP) to the mobile station (MS) is a downlink (DL), and a reverse line is an uplink (UL). According to the hopping pattern, the frequency channel is changed for each TDMA / TDD frame (see Non-Patent Document 4). The time frame (hopping period) of the control channel has a length of 5 ms. As shown in FIG. 6, the time frame (TDMA / TDD frame length) includes a sensing period, four downlinks DL1 to DL4, and four uplinks UL1 to UL4. Further, the sensing period is, for example, 200 μs. The downlink and uplink slots are, for example, 600 μs. Each of the four downlinks DL1 to DL4 and the four uplinks UL1 to UL4 constitutes a slot.

The length of the sensing period is preferably 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.

  Further, 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.

  The configuration of the data channel is shown in FIG. 8, and the specification is shown in FIG. As shown in FIG. 8, the slot length of the data channel is an integer (M) times the control channel slot, and the data channel slot is synchronized with the control channel slot. The number of frequency channels used is an integer (N) times the control channel, and an available frequency other than the control channel is used.

  Further, in the logical channel, as shown in FIG. 10, a portion obtained by removing the guard time from one slot of the control channel is defined as a control channel, and a portion obtained by removing the guard time from one slot of the data channel is defined as a data channel.

  FIG. 11 shows the configuration of the control channel. In FIG. 11, SP is a short preamble, for example, is repeated 16 times and is “16 × 8” bits. LP is a long preamble, which is repeated twice, for example, and is “64 × 2” bits. CRC indicates a CRC32 parity bit of control information, Pad indicates padding, and T indicates a trellis closing bit. In addition, signals other than SP and LP are convolutionally encoded. The Pad signal is padded so that the T signal becomes the end of the control channel.

  Control information transmitted using the fourth downlink slot (DL4) of the control channel includes broadcast information, registration information, and call information. A more specific control information structure is shown in FIG. In FIG. 12, AP-ID is a unique number of a base station (cell), and is 16 bits, for example. HP is information on the hopping pattern of the control channel, and is 8 bits, for example. CT indicates the control type and is, for example, 8 bits. L represents the total number of bits of information data, and is 10 bits, for example. The broadcast information is information on the frequency channel that the AP is scheduled to use (the reception station-side scheduled use frequency information or the transmission station-side scheduled use frequency information, for example, 80 bits) and the broadcast period of the broadcast information. Is included (for example, 8 bits). The broadcast information is used for channel sensing range limitation and frequency channel management between APs. In addition, the registration information includes information of the MS that has completed registration with respect to the registration information from the MS. Specifically, the registration information is described as a unique number of the mobile terminal (symbol “MS-ID”, for example, 16 bits) or a unique number assigned to the MS-ID (symbol “ID”), For example, 8 bits). Further, the call information includes information for calling the MS from the AP. Since a broadcast or individual control channel is used, n MSs can be handled individually. A specific structure of the call information is shown in FIG. In FIG. 13, ID is a unique number assigned to each mobile terminal by the base station, and is 8 bits, for example. RT is a request type, for example, 5 bits. SN is a list of slots used for communication, and is 3 bits, for example. The call information includes n sets of ID, RT, and SN. The fourth downlink slot (DL4) of the control channel is called a downlink common control channel.

  Control information transmitted using the fourth uplink slot (UL4) of the control channel includes registration information, release information, and transmission start information. A specific configuration of the control information is shown in FIG. In FIG. 14, AP-ID is a base station (cell) specific number, for example, 16 bits. The ID is a unique number assigned to the mobile terminal by the base station, and is 8 bits, for example. CT is a control type, for example, 8 bits. L is the total number of bits of information data, for example, 10 bits. The registration information includes information for registering the MS with the AP. More specifically, the registration information includes a unique number of the mobile terminal (symbol “MS-ID”, 16 bits), a maximum data rate that can be transmitted and received (symbol “MR”, 8 bits), received power (Denoted as “RL” and 8 bits). The release information includes information for releasing the MS registered in the AP. Further, the transmission start information includes information for starting transmission of the data channel. More specifically, the transmission start information includes a unique number of the transmission destination (described as symbol “ID” and 8 bits). The uplink fourth slot (UL4) of the control channel is referred to as an uplink common control channel.

  Control information transmitted bidirectionally using the first slot (DL1 / UL1) to the third slot (DL3 / UL3) of the control channel includes channel selection information, data channel information, transmission end information, and response information. is there. The channel selection information is information necessary for data channel transmission. The channel selection information includes a slot that can be used for a data channel (designated as “ST”, 8 bits), a frequency channel that can be used (designated as “MAP”, 80 bits), and a receivable data rate (symbol). “MR” (8 bits) and received power (symbol “RL”, 8 bits) information. The data channel information is information on data channels that are transmitted simultaneously. The data channel information includes a slot used by the data channel (referred to as “ST”, 8 bits), a usable frequency channel (referred to as “MAP”, 80 bits), a modulation scheme, a coding rate, and the number of transmission antennas. Information (referred to as “RATE”, 8 bits). The transmission end information includes information for ending transmission of the data channel. Further, the response information specifically includes a response number (referred to as “RN”, 8 bits). A more specific configuration of control information is the same as in FIG. Further, the first slot (DL1 / UL1) to the third slot (DL3 / UL3) of the control channel are referred to as individual control channels.

  The configuration of the data channel is shown in FIG. In FIG. 15, SP is a short preamble, LP is a long preamble, DL is the number of bytes of the DATA signal, DATA is data, CRC is a CRC32 parity bit of the DL signal and the DATA signal, Pad is Padding, and T is a trellis termination bit. . Note that signals other than SP and LP are convolutionally encoded. The Pad signal is padded so that the T signal is at the end of the data channel.

  Next, a specific communication procedure of radio communication system 1 in the present embodiment will be described.

  In the communication procedure described below, the receiving station 11 (also referred to as a data receiving node) generates channel selection information, and the transmitting station 12 (also referred to as a data transmitting node) determines data channel information. As a result, the data channel information and the data channel can be transmitted at the same time, and the channel sensing necessary for sending one slot of the data channel can be reduced to twice compared to the procedure of Non-Patent Document 4 described above. it can. However, when the mobile terminal (MS) generates channel selection information, it is necessary to know the frequency channels that can be used in the cell, and this can be obtained from the broadcast information described above.

  A downlink data transmission procedure in the wireless communication system 1 is shown in FIG. In FIG. 16, the receiving station 11 is an MS and the transmitting station 12 is an AP. In FIG. 16, it is assumed that the MS knows the frequency channels that can be used in the cell based on the broadcast information.

  In such a situation, the transmitting means of the transmitting station 12 (AP) transmits call information (transmission start) to the receiving station 11 (MS).

  Next, the receivable frequency information acquisition unit 114 of the MS acquires channel selection information (which has the same meaning as the receivable frequency information) until the transmission end information is received by the receiving unit. Then, the receivable frequency information transmitting unit 115 of the MS transmits channel selection information to the AP for each frame until the transmission end information is received by the receiving unit.

  The receivable frequency information receiving unit 125 of the AP receives channel selection information from the MS until transmission of all data is completed. Then, the AP transmittable frequency information acquisition unit 124 performs channel sensing for each frame until transmission of all data is completed, and acquires transmittable frequency information. The data transmission frequency information acquisition unit 126 acquires data transmission frequency information using the received channel selection information and transmittable frequency information. Here, the data transmission frequency information acquisition unit 126 holds the maximum receivable data rate and the maximum transmittable data rate, and it is preferable to acquire the data transmission frequency information so as not to exceed the maximum data rate. is there.

  Next, the AP transmission means (the data transmission frequency information transmission unit 127 and the data transmission unit 128) transmits the data transmission frequency information and the data to the MS at the same time. The data transmission frequency information transmission unit 127 transmits data transmission frequency information using the control channel, and the data transmission unit 128 transmits data using the data channel.

When the AP finishes transmitting all data, the AP transmits transmission end information to the MS to complete the procedure. Here, if the set of frequency channels in the broadcast information, channel selection information, and data channel information is MAP _B , MAP _S , and MAP _C , the following Equation 1 is satisfied.

  Next, the uplink data transmission procedure is shown in FIG. The procedure for determining the data channel information is symmetric with FIG. That is, the MS transmits transmission start information to the AP. Next, the AP transmits channel selection information to the MS for each frame until receiving the transmission end information. Then, the MS determines data channel information from the channel selection information and the sensing result for each frame until transmission of all data is completed, and transmits the data channel information together with the data channel to the AP. When the MS completes transmission of all data, the MS transmits transmission end information to the AP.

  Next, a procedure for one-side communication from the mobile terminal (MS1) to the mobile terminal (MS2) via the AP will be described. FIG. 18 is a diagram describing this procedure.

  First, the MS 1 transmits transmission start information to the AP. Next, the AP transmits call information (transmission start) to the MS 2 that is the transmission destination ID of the transmission start information. The MS 2 transmits channel selection information to the AP for each frame until receiving the transmission end information. The AP determines the maximum data transmission rate to the MS 2 from the channel selection information from the MS 2 and the sensing result for each frame until the transmission end information is received from the MS 1 and transmits it to the MS 1 as channel selection information. The MS 1 determines data channel information from the channel selection information and the sensing result for each frame until transmission of all data is completed, and transmits the data channel information to the AP together with the data channel. The AP determines the data channel information from the channel selection information from MS2 and the sensing result for each frame until receiving the transmission end information from MS1, and transmits the data channel information to MS2 together with the data channel. When the transmission of all data is completed, the MS 1 transmits transmission end information to the AP. When the AP receives the transmission end information, the AP transmits the transmission end information to the MS 2.

  As described above, according to the present embodiment, it is possible to improve the reduction in data transmission throughput, which is a problem in the DSA system using CSMA / CA, FDMA, and TDMA in combination, and to realize high-efficiency frequency sharing such as the ISM band. Specifically, a communication procedure and a logical channel in which the receiving station 11 transmits a channel sensing result, and the transmitting station 12 acquires data transmission frequency information that is a data transmission frequency and simultaneously transmits the data transmission frequency information and data. According to the configuration, it is possible to reduce the number of times of channel sensing necessary for determining the data transmission frequency, and to avoid a decrease in data transmission throughput. However, when data transmission frequency information and data are transmitted simultaneously, the PAPR of the transmission signal increases, but this can be avoided by delaying the transmission timing of the data channel.

  Further, according to the present embodiment, the receiving station and the transmitting station can narrow the range of the sensing frequency in the receiving station and the transmitting station by grasping the frequency scheduled to be used by the base station. Channel sensing processing can be speeded up.

  Note that the processing in the present embodiment may be realized by software. Then, this software may be distributed by software download or the like. Further, this software may be recorded and distributed on a recording medium such as a CD-ROM. This also applies to other embodiments in this specification. The software that realizes the receiving station in the present embodiment is the following program. That is, this program senses a computer from a predetermined frequency band and obtains receivable frequency information that is information of one or more receivable frequencies, and the receivable frequency. Using a frequency different from the frequency indicated by the information, a receivable frequency information transmitting unit that transmits the receivable frequency information to the transmitting station, and data transmission frequency information indicating a frequency for transmitting data from the transmitting station are received. A data transmission frequency information receiving unit and a program for functioning as a data receiving unit that receives data using a frequency indicated by the data transmission frequency information.

  The software that realizes the transmitting station in the present embodiment senses a computer from a predetermined frequency band and obtains transmittable frequency information that is information of one or more frequencies that can be transmitted. An information acquisition unit, a receivable frequency information receiving unit that receives the receivable frequency information from a receiving station, one or more receivable frequencies indicated by the receivable frequency information, and one or more transmissions indicated by the transmittable frequency information A data transmission frequency information acquisition unit that determines one or more frequencies for transmitting data from among the one or more frequencies that coincide with each other, and acquires data transmission frequency information that is information on the frequencies; Data for transmitting the data transmission frequency information to the receiving station using a frequency different from the frequency indicated by the transmittable frequency information And Shin frequency information transmitting unit, by using the frequency indicated by the data transmission frequency information, a program, to function as a data transmission unit that transmits data to the receiving station.

  In the above program, in the step of transmitting information, the step of receiving information, etc., processing performed by hardware, for example, processing performed by a modem or an interface card in the transmitting step (only performed by hardware). Not included).

  Further, the computer that executes the program may be singular or plural. That is, centralized processing may be performed, or distributed processing may be performed.

  In each of the above embodiments, two or more communication means (such as a receivable maximum data rate information transmitting unit and a receiving station side scheduled use frequency information receiving unit) existing in one device are physically one medium. It goes without saying that it may be realized.

In each of the above embodiments, each process (each function) may be realized by centralized processing by a single device (system), or by distributed processing by a plurality of devices. May be.
The present invention is not limited to the above-described embodiments, and various modifications are possible, and it goes without saying that these are also included in the scope of the present invention.

  As described above, the wireless communication system according to the present invention has an effect of preventing a decrease in data transmission throughput due to a time delay due to exchange of channel sensing results in a dynamic spectrum access system. It is useful as a wireless communication system.

DESCRIPTION OF SYMBOLS 1 Wireless communication system 11 Receiving station 12 Transmitting station 111 Receivable maximum data rate storage part 112 Receivable maximum data rate information transmission part 113 Receiving station side use frequency information receiving part 114 Receivable frequency information acquisition part 115 Receivable frequency information transmission Unit 116 data transmission frequency information receiving unit 117 data receiving unit 121 transmittable maximum data rate storage unit 122 receivable maximum data rate information receiving unit 123 transmitting station side scheduled use frequency information receiving unit 124 transmittable frequency information obtaining unit 125 receivable frequency Information reception unit 126 Data transmission frequency information acquisition unit 127 Data transmission frequency information transmission unit 128 Data transmission unit

Claims (9)

A wireless communication system in which a receiving station and a transmitting station communicate wirelessly,
The receiving station is
A receivable frequency information acquisition unit that performs first sensing from a predetermined frequency band and acquires receivable frequency information that is information of one or more receivable frequencies;
Receivable frequency information transmitting unit that transmits the receivable frequency information to the transmitting station using a frequency different from the frequency indicated by the receivable frequency information;
A data transmission frequency information receiving unit for receiving data transmission frequency information indicating a frequency for transmitting data from the transmitting station;
Using a frequency indicated by the data transmission frequency information, and a data receiving unit for receiving data,
The transmitting station is
Transmittable frequency information acquisition unit that performs second sensing from a predetermined frequency band and acquires transmittable frequency information that is information of one or more frequencies that can be transmitted;
A receivable frequency information receiving unit that receives the receivable frequency information from the receiving station;
One or more for transmitting data from one or more matching frequencies among one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information A data transmission frequency information acquisition unit that determines the frequency of the data and acquires data transmission frequency information that is information of the frequency;
A data transmission frequency information transmitting unit that transmits the data transmission frequency information to the receiving station using a frequency different from the frequency indicated by the transmittable frequency information;
A wireless communication system comprising: a data transmission unit that transmits data to the receiving station using a frequency indicated by the data transmission frequency information. The transmitting station is
Further comprising a transmittable maximum data rate storage unit storing information of a maximum transmittable data rate,
The data transmission frequency information acquisition unit is
One or more that match between one or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information so as not to exceed the maximum transmittable data rate The wireless communication system according to claim 1, wherein one or more frequencies for transmitting data are determined from among the frequencies, and data transmission frequency information that is information on the frequencies is acquired. The receiving station is
A maximum receivable data rate storage section that stores information on the maximum receivable data rate;
A receivable maximum data rate information transmitting unit for transmitting the receivable maximum data rate information to the transmitting station;
The transmitting station is
A receivable maximum data rate information receiving unit for receiving information on the maximum receivable data rate from the receiving station;
The data transmission frequency information acquisition unit is
One or more receivable frequencies indicated by the receivable frequency information and one or more transmittable frequencies indicated by the transmittable frequency information so as not to exceed the maximum transmittable data rate and the maximum receivable data rate. 3. The wireless communication system according to claim 2 , wherein one or more frequencies for transmitting data are determined from one or more matching frequencies, and data transmission frequency information, which is information on the frequencies, is acquired. The receiving station is
A use scheduled frequency information receiving unit for receiving the scheduled use frequency information, which is information of a frequency scheduled to be used by the base station, from the base station;
The receivable frequency information acquisition unit,
Among the one or more frequencies indicated by the scheduled use frequency information and the one or more frequencies indicated by the frequency band, sensing is performed from one or more matching frequencies, and information on one or more frequencies that can be received is used. The wireless communication system according to claim 1, wherein certain receivable frequency information is acquired. The transmitting station is
A use scheduled frequency information receiving unit for receiving the scheduled use frequency information, which is information of a frequency scheduled to be used by the base station, from the base station;
The transmittable frequency information acquisition unit
Among the one or more frequencies indicated by the scheduled use frequency information and the one or more frequencies indicated by the frequency band, sensing is performed from one or more matching frequencies, and information on one or more frequencies that can be transmitted is used. The radio | wireless communications system in any one of Claims 1-4 which acquires a certain transmittable frequency information. The data transmission frequency information transmission unit and the data transmission unit are:
The wireless communication system according to claim 1, wherein the data transmission frequency information and the data are simultaneously transmitted to the receiving station. The frequency different from the frequency indicated by the receivable frequency information, the frequency different from the frequency indicated by the transmittable frequency information, or the frequency different from the frequency indicated by the receivable frequency information and the frequency indicated by the transmittable frequency information. 7. The radio communication system according to claim 1, wherein the different frequency is a frequency of one common control channel among one or more predetermined common control channels. The receiving station which comprises the radio | wireless communications system in any one of Claims 1-7. A transmitting station constituting the wireless communication system according to claim 1.

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