WO2015163335A1 - 無線通信端末、メモリーカード、および無線通信方法 - Google Patents
無線通信端末、メモリーカード、および無線通信方法 Download PDFInfo
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- WO2015163335A1 WO2015163335A1 PCT/JP2015/062158 JP2015062158W WO2015163335A1 WO 2015163335 A1 WO2015163335 A1 WO 2015163335A1 JP 2015062158 W JP2015062158 W JP 2015062158W WO 2015163335 A1 WO2015163335 A1 WO 2015163335A1
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W72/00—Local resource management
- H04W72/04—Wireless resource allocation
- H04W72/044—Wireless resource allocation based on the type of the allocated resource
- H04W72/0446—Resources in time domain, e.g. slots or frames
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W28/00—Network traffic management; Network resource management
- H04W28/16—Central resource management; Negotiation of resources or communication parameters, e.g. negotiating bandwidth or QoS [Quality of Service]
- H04W28/18—Negotiating wireless communication parameters
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- H—ELECTRICITY
- H04—ELECTRIC COMMUNICATION TECHNIQUE
- H04W—WIRELESS COMMUNICATION NETWORKS
- H04W84/00—Network topologies
- H04W84/02—Hierarchically pre-organised networks, e.g. paging networks, cellular networks, WLAN [Wireless Local Area Network] or WLL [Wireless Local Loop]
- H04W84/10—Small scale networks; Flat hierarchical networks
- H04W84/12—WLAN [Wireless Local Area Networks]
Definitions
- Embodiments described herein relate generally to a wireless communication terminal, a memory card, and a wireless communication method.
- the channels to be used are expanded sequentially from adjacent channels, and a plurality of wireless channels are used simultaneously. This realizes high-speed wireless communication with a maximum width of 160 MHz.
- information on previously available channels is shared on the transmission / reception side by exchanging control frames, and the bandwidth used for data transmission / reception is determined.
- Embodiment of this invention aims at improving the utilization efficiency of the whole channel.
- a wireless communication terminal as an embodiment of the present invention includes a transmission unit, a reception unit, and a control unit.
- the transmission means transmits first information specifying one or more resource blocks for which allocation is requested among the plurality of resource blocks.
- the receiving means receives second information specifying one or more resource blocks allocated according to the first information.
- the control means controls to transmit / receive a signal in the resource block specified by the second information.
- wireless communications system provided with the base station and terminal which concern on 1st Embodiment.
- wireless communication apparatus mounted in the base station which concerns on 1st Embodiment. 1 is a perspective view of a wireless device according to an embodiment of the present invention.
- IEEE Std 802.11 TM -2012 and IEEE Std 802.11ac TM -2013, known as wireless LAN standards, are all incorporated herein by reference.
- FIG. 1 is a configuration diagram of a wireless communication system including a wireless communication base station and a wireless communication terminal according to the first embodiment.
- This wireless communication system performs communication according to an arbitrary communication method.
- the IEEE 802.11 standard is assumed as the communication method, but the communication method is not limited to this.
- the wireless communication base station is referred to as a base station
- the wireless communication terminal is referred to as a terminal.
- a base station is also a form of a terminal, and differs from a terminal of a non-base station in that it has a relay function.
- STAs Terminals
- AP Access Point
- the connection means a state in which a radio link is established, and a radio link is established by completing the exchange of parameters necessary for communication through an association process with the base station.
- the base station 101 can receive or transmit simultaneously with a plurality of terminals by assigning one or more channels to each terminal using a plurality of radio channels (hereinafter referred to as channels) within a predetermined frequency band.
- a communication method is sometimes called channel-based OFDMA (Orthogonal Frequency Division Multiple Access) or MU-MC (Multi User-Multi Channel).
- reception or transmission is performed simultaneously, but this is only an example.
- transmission and reception can be performed at independent timing for each terminal.
- channels 1 to channel 8 there are eight channels from channel 1 to channel 8 in order from the lowest frequency as a plurality of channels in a predetermined frequency band.
- “1 to 8” of channels 1 to 8 are channel numbers.
- the base station and each terminal are depicted as if they were equipped with one antenna, but this is only a schematic diagram, and in practice it may be equipped with one or more antennas. Good.
- the base station and the terminal are equipped with wireless communication devices for communicating with each other.
- the wireless communication device mounted on the terminal is a communication device that is a target of communication with the wireless communication device mounted on the base station.
- the wireless communication device mounted on the base station is a communication device that is a target of communication with the wireless communication device mounted on the terminal.
- a method of assigning in units of subcarriers may be used. More specifically, in a continuous frequency region (for example, within a 20 MHz channel width, a 40 MHz channel width, an 80 MHz channel width, and a 160 MHz channel width), a resource block having a plurality of subcarriers as a unit (may be called a subchannel) May be assigned to each terminal, and OFDMA communication may be performed in which simultaneous transmission to a plurality of terminals or simultaneous reception from a plurality of terminals is performed.
- the resource block is a frequency resource configured with one or a plurality of subcarriers as one unit.
- the resource block When configured with a plurality of subcarriers, the resource block is continuous even if the arrangement of each subcarrier is continuous. You don't have to. In this embodiment, it is called a resource block, but another expression can be used. For example, it may be called a subchannel or a frequency block instead of a resource block. It is also possible to assign a plurality of subcarriers arranged discontinuously as a resource block to one wireless terminal.
- a plurality of channels are arranged in the frequency domain, and the frequency domain of one channel is, for example, 20 MHz.
- the frequency region of the bandwidth of one channel or the frequency region of the bandwidth obtained by bundling a plurality of channels corresponds to the continuous frequency region.
- a plurality of subcarriers that are continuous in frequency are arranged orthogonal to each other.
- a resource block having one or more subcarriers as a unit is allocated to one or more terminals.
- resource blocks are allocated to terminal 1 and terminal 2 in the frequency domain of one channel. Simultaneous transmission to a plurality of terminals or simultaneous reception from a plurality of terminals is performed with resource blocks allocated to the respective terminals.
- Such OFDMA communication is particularly expressed as resource block-based OFDMA communication.
- the channel of the embodiment described below is replaced with a resource block, the following embodiment can be similarly applied.
- two subcarriers are arranged as guard subcarriers in resource blocks allocated to terminal 1 and terminal 2.
- the number of guard subcarriers is not limited to two, and may be arbitrary as long as it is one or more. Also, it is not essential to arrange guard subcarriers between resource blocks to be allocated to terminals, and it is also possible not to arrange guard subcarriers between resource blocks.
- the number of subcarriers per resource block may be the same, or the number of subcarriers in one resource block may be allowed to differ.
- the bandwidth of the subcarriers arranged in the frequency domain may be different.
- the bandwidth of individual subcarriers arranged in the channel is a frequency of a bandwidth of 40 MHz in which two channels are bundled. It may be smaller than the bandwidth of individual subcarriers arranged in the region.
- resource block based OFDMA it is possible to combine a subcarrier unit scheme with MU-MC. For example, it may be allowed to assign to a terminal in units of subcarriers or resource blocks in each of a plurality of 20 MHz channels. In this case, the number of subcarriers in each resource block belonging to the same channel is the same, but the number of subcarriers may be different in each resource block.
- One or a plurality of resource blocks in one channel may be allocated to the terminal, or a plurality of resource blocks belonging to a plurality of channels may be allocated to the terminal.
- NAV Network Allocation Vector
- a subcarrier unit scheme is performed in combination with MU-MC, specifically, for example, when a plurality of 20 MHz channels are allocated to terminals in units of subcarriers or resource blocks, the MU-MC described below is used. This may be considered in the embodiment based on the channels.
- FIG. 2 is a block diagram of a wireless communication apparatus mounted on the terminal 201.
- the terminals 202 and 203 also include wireless communication devices, and since these wireless communication devices have the same configuration as the wireless communication device of the terminal 201, description thereof is omitted.
- the wireless communication device includes a wireless communication integrated circuit.
- the wireless communication device of the terminal 201 includes one or more antennas, a PHY processing unit and radio unit 20, a MAC processing unit 30, and an upper layer processing unit 40.
- the MAC processing unit 30 includes a transmission unit 31, a reception unit 32, an access control unit 33, and a control unit 34, and corresponds to the wireless communication integrated circuit or the communication processing device of this embodiment.
- the PHY processing unit and the radio unit 20 include one or a plurality of transmission / reception processing units. First to Xth transmission / reception processing units are provided, where X is an integer of 1 or more. An antenna is connected to each transmission / reception processing unit.
- the control unit is divided into the control unit 34 and the access control unit 33, but these may be combined into one control unit.
- the PHY processing unit and the radio unit 20 are configured by an RF integrated circuit as an example, and the MAC processing unit 30 is configured by a baseband integrated circuit as an example. At this time, the RF integrated circuit 20 and the MAC processing unit 30 may be integrated into one integrated circuit.
- each transmission / reception processing unit may be arranged for each channel.
- one transmission / reception processing unit may be arranged for a plurality of channels.
- 8 transmission / reception processing units are provided to perform processing for each channel.
- an antenna is connected to each transmission / reception processing unit, but one antenna may be connected to a plurality of transmission / reception processing units.
- each transmission / reception processing unit may operate so as to extract a signal of a channel designated by the own processing unit using an analog filter, a digital filter, or both of them.
- Information on the channel processed by each transmission / reception processing unit is managed by the control unit 34 in the MAC control unit 30, and the control unit 34 instructs each transmission / reception processing unit about the channel to be processed.
- the access control unit 33 manages channel access and controls frame transmission at a desired timing.
- the transmission unit 31 generates and transmits a frame.
- the transmission unit 31 When the transmission unit 31 is instructed to transmit a frame from the access control unit 33, the transmission unit 31 generates the instructed frame and outputs the generated frame to the PHY processing unit and the radio unit 20.
- the PHY processing unit and the radio unit 20 input one or more frames input from the transmission unit 31 to the corresponding one or more transmission / reception processing units.
- Each transmission / reception processing unit performs a desired physical layer process on the frame input from the transmission unit 31 to perform D / A conversion, frequency conversion, and the like, and transmits a signal from the antenna to the space as a radio wave.
- the frame according to the present embodiment may be called not only a frame in the IEEE 802.11 standard but also a packet.
- the access control unit 33 and the control unit 34 may access the storage device for information to be transmitted to the base station and read the information, or store the information received from the base station in the storage device.
- the storage device may be a buffer (internal memory) provided in the access control unit 33 or the control unit 34 or both, or a buffer (external memory) provided outside the access control unit 33 or the control unit 34.
- the storage device may be a volatile memory such as a DRAM or a non-volatile memory such as a NAND or MRAM.
- the storage device may be an SSD, a hard disk, or the like.
- the PHY processing unit and the radio unit 20 extract the signal of the corresponding channel from the signal received via the antenna, perform the receiving process, and output the processed frame to the receiving unit 32 To do.
- the reception processing includes, for example, desired physical layer processing such as frequency conversion to baseband, A / D conversion, analysis of a physical header of a frame after A / D conversion, and demodulation processing.
- the receiving unit 32 analyzes the MAC header of the frame input from the PHY processing unit and the radio unit 20. If the receiving unit 32 determines that the received frame is a data frame from the analysis result of the MAC header of the received frame, the receiving unit 32 outputs the frame to the upper processing unit 40 as necessary. If the received frame is a management frame or a control frame, the frame is output to the access control unit 33, and an ACK frame generation instruction is output to the access control unit 33 as necessary, or directly to the transmission unit 31. Output.
- the management frame is a frame used for managing a communication link with another terminal.
- a beacon frame As an example, a beacon frame, an association request frame (a connection request frame for requesting connection to a base station), an association There are response frames (connection response frames that are response frames of connection request frames) and the like.
- the control frame is a frame used for control when a management frame and a data frame are transmitted / received (exchanged) to / from another wireless communication apparatus.
- an RTS Request to Send
- CTS Clear to Send
- ACK Acknowledgement
- This carrier sense information includes physical carrier sense information related to busy and idle of a medium (CCA: Clear Channel Assessment) input from the PHY processing unit and the radio unit 20, and a medium reservation time described in a received frame. Both virtual carrier sense information based may be included. If any one of the carrier sense information indicates busy, the medium is regarded as busy, and signal transmission during that time is prohibited. In the IEEE 802.11 standard, the medium reservation time is described in a Duration field in the MAC header (see FIG. 4 described later). When receiving a frame addressed to another wireless communication device (not addressed to itself), the receiving unit 32 determines that the medium is virtually busy during the medium reservation time. Such a mechanism for virtually determining that a medium is busy, or a period during which a medium is virtually busy is referred to as NAV (Network Allocation Vector).
- NAV Network Allocation Vector
- the terminal 201 is not connected to the base station 101 yet.
- the terminal 201 desires to connect to the base station 101, the terminal 201 performs carrier sense of each channel from the channel 1 to the channel 8 via the PHY processing unit and the radio unit 20.
- the reception unit 32 is notified of the carrier sense result in each channel.
- the access control unit 33 includes selection means for selecting a channel desired to be used based on the carrier sense result in each channel, and selects a channel desired to be used using the selection means. For example, if channels 1 and 2 are busy and channels 3 to 8 are idle, a channel is selected from channel 3 to channel 8.
- the method for determining the number of channels to be used may be arbitrary, and may be determined according to the amount of communication data, or may be determined below a predetermined maximum number. In the latter case, if the number of idle channels is equal to or greater than the maximum number, the maximum number may be determined. Moreover, what channel should be used among idle channels may be determined under an arbitrary condition. As an example, the selection may be made so as to satisfy the condition that continuous channels are selected.
- the channel selected here is a channel for requesting allocation to the base station, and is called a use request channel.
- the transmission unit 31 of the terminal 201 generates a connection request frame, that is, an association request frame under the control of the access control unit 33.
- use request channel information specifying the use request channel is included in the association request frame.
- the use request channel can be specified by an arbitrary method as long as the use request channel number can be specified. As an example, assuming that consecutive channels are specified, specify them in the form of a set of the smallest channel number (minimum channel number) of consecutive channels and channel width information that specifies the desired number of channels or bandwidth. May be. When one channel width is 20 MHz and two channels are to be used, the channel width information is 2 (in the case of the number of channels) or 40 MHz (in the case of bandwidth).
- It may be a set of the largest channel number (maximum channel number) of consecutive channels and channel width information specifying the desired number of channels or bandwidth. Alternatively, it may be a set of the smallest channel number (minimum channel number) and the largest channel number (maximum channel number) of consecutive channels.
- transmission is performed using one or a plurality of channels including at least a predetermined channel.
- a primary channel of common recognition as a system such as IEEE802.11ac and all the terminals monitor the primary channel transmission is performed on at least the primary channel.
- it may be transmitted by a plurality of channels including the primary channel, or may be transmitted by all channels supported by the base station 101.
- the primary channel may be determined in advance, for example, channel 1.
- the primary channel may be notified by a beacon frame.
- the receiving unit 32 of the terminal 201 receives an association response frame that is a response to the association request frame from the base station 101, and determines whether the association response frame includes assignment information that specifies a channel assigned by the base station. To do.
- allocation information is included, the control unit 34 is notified of the information.
- the allocation information may be notified to the control unit 34 via the access control unit 33, or may be notified directly to the control unit 34 without using the access control unit 33.
- the control unit 34 grasps the channel specified by the allocation information as a channel to be used thereafter, and controls each transmission / reception processing unit so as to perform a standby operation on the channel.
- the standby operation is an operation of waiting for a frame transmitted from the base station.
- the control unit 34 may control the transmission / reception processing units other than the transmission processing unit necessary for the channel standby operation to stop the operation.
- FIG. 3 is a block diagram of a wireless communication apparatus mounted on the base station 101.
- the radio communication apparatus of the base station 101 includes one or more antennas, a PHY processing unit and radio unit 70, a MAC processing unit 80, and an upper layer processing unit 90.
- this wireless communication apparatus is configured by an integrated circuit for wireless communication.
- the MAC processing unit 80 includes a transmission unit 81, a reception unit 82, an access control unit 83, and a control unit 84.
- the PHY processing unit and radio unit 70 includes one or a plurality of transmission / reception processing units. First to Xth transmission / reception processing units are provided, where X is an integer of 1 or more. An antenna is connected to each transmission / reception processing unit.
- the PHY processing unit and the radio unit 70 are configured by an RF integrated circuit as an example, and the MAC processing unit 80 is configured by a baseband integrated circuit as an example. At this time, the RF integrated circuit 70 and the MAC processing unit 30 may be integrated into one integrated circuit.
- each transmission / reception processing unit may be arranged for each channel.
- one transmission / reception processing unit may be arranged for a plurality of channels.
- 8 transmission / reception processing units are provided to perform processing for each channel.
- an antenna is connected to each transmission / reception processing unit, but one antenna may be connected to a plurality of transmission / reception processing units.
- each transmission / reception processing unit may operate so as to extract a signal of a channel designated by the own processing unit using an analog filter, a digital filter, or both of them.
- Information about the channels processed by each transmission / reception processing unit is managed by the control unit 84 in the MAC control unit 80, and the control unit 84 instructs each transmission / reception processing unit about the channel to be processed.
- the PHY processing unit and the radio unit 70 receive a signal via an antenna, extract a signal of a corresponding channel, perform a reception process, and output the processed frame to the reception unit 82.
- the reception processing includes, for example, desired physical layer processing such as frequency conversion to baseband, A / D conversion, analysis of a physical header of a frame after A / D conversion, and demodulation processing.
- the receiving unit 82 analyzes the MAC header of the frame input from the PHY processing unit and the radio unit 70. If the receiving unit 82 determines from the analysis result of the MAC header of the received frame that the received frame is a data frame, the receiving unit 82 outputs the processed frame to the upper processing unit 90 as necessary.
- the frame is output to the access control unit 33, and an ACK frame generation instruction is output to the access control unit 33 as necessary, or directly to the transmission unit 31. Output.
- the receiving unit 82 manages carrier sense information in the same manner as the wireless communication device of the terminal. As described above, the carrier sense information may include both physical carrier sense information and virtual carrier sense information.
- the access control unit 83 manages channel access and controls frame transmission at a desired timing.
- the access control unit 83 includes control means or assignment means for performing channel assignment of each terminal, and performs channel assignment to each terminal by the control means or assignment means.
- the access control unit 83 manages the channels assigned to each terminal.
- the access control unit 83 assigns a channel to each terminal based on use request channel information from each terminal. Basically, a channel is allocated to each terminal so as not to overlap. However, it is also possible to perform control so that duplicate channels are allocated at each terminal, and duplicate channels are not used during actual communication.
- the access control unit 83 uses the use request channel of the terminal 201 and the channel already assigned to the already connected terminal.
- the channel assigned to the terminal 201 is determined. As an example, if the use request channel of the terminal 201 is not assigned to any other terminal, all of the use request channels are assigned to the terminal 201. If a part of the usage request channel of the terminal 201 has been allocated, but the remaining part is not allocated, only the remaining part is allocated to the terminal 201. There may be a configuration in which a channel other than the use request channel requested from the terminal 201 is allocated to the terminal 201 as in an embodiment described later.
- the access control unit 83 instructs the transmission unit 81 to generate and transmit an association response frame including allocation information specifying the channel allocated to the terminal 201.
- the channel designation method in the allocation information may be any method as long as the channel number allocated to the terminal can be specified. As an example, the same format as the usage request channel information can be used. In this case, it may be specified in the form of a set of the smallest channel number (minimum channel number) of the assigned channels and channel width information specifying the number of assigned channels or bandwidth. When one channel width is 20 MHz and two channels are allocated, the channel width information is 2 (in the case of the number of channels) or 40 MHz (in the case of bandwidth).
- It may be a set of the largest channel number (maximum channel number) of consecutive channels and channel width information specifying the desired number of channels or bandwidth.
- it may be a set of the smallest channel number (minimum channel number) and the largest channel number (maximum channel number) of the allocated channels.
- the access control unit 83 controls to communicate simultaneously with a plurality of terminals using a channel assigned to each terminal.
- the communication direction includes a downlink from the base station to each terminal and an uplink from each terminal to the base station.
- simultaneous downlink communication it may be performed on the uplink.
- a base station transmits an RTS frame simultaneously on all channels assigned to each terminal, and each terminal can receive an RTS frame, or the channel is idle for a certain timing before the RTS frame.
- the CTS frame is transmitted after SIFS (short interframe space) from the completion of reception of the RTS frame on the channel. Details of SIFS will be described in other embodiments described later.
- the base station may transmit a data frame from the base station simultaneously after SIFS from the completion of reception of the CTS frame on the channel in which the CTS frame is returned. Further, the ACT frame returned after SIFS from the completion of reception of the data frame from each terminal may be received simultaneously on the channel that transmitted the data frame.
- the time of data frame transmission it is also possible to bundle continuous channels at each terminal and transmit or transmit MIMO like one frequency band. Thereby, the effect of speeding up and robustness can be obtained.
- information necessary for MIMO transmission may be obtained from each terminal in advance using a management frame.
- the access control unit 83 and the control unit 84 may access the storage device to read information to be transmitted to the terminal, or store the information received from the terminal in the storage device.
- the storage device may be a buffer (internal memory) provided in the access control unit 83 or the control unit 84 or both, or a buffer (external memory) provided outside the access control unit 83 or the control unit 84.
- the storage device may be a volatile memory such as a DRAM or a non-volatile memory such as a NAND or MRAM.
- the storage device may be an SSD, a hard disk, or the like.
- the transmission unit 81 generates and transmits a frame (management frame, control frame, data frame) under the control of the access control unit 83.
- the transmission unit 81 When the generation and transmission of a frame is instructed from the access control unit 83, the transmission unit 81 generates a designated frame and outputs the generated frame to the PHY processing unit and the radio unit 70.
- the frame to be transmitted is a data frame
- the data stored in the body field of the data frame is acquired from the upper layer processing unit 40.
- the PHY processing unit and radio unit 70 inputs one or more frames generated by the transmission unit 81 to the corresponding one or more transmission / reception processing units.
- Each transmission / reception processing unit performs a desired physical layer process on the frame input from the transmission unit 81, performs D / A conversion, frequency conversion, and the like, and transmits a signal from the antenna to the space as a radio wave.
- FIG. 4 shows an example of a frame format used in wireless communication in this embodiment.
- Management frames such as the above-described association request frame or association response frame have this frame format.
- This frame format includes fields of a preamble, a MAC header, a frame body, and an FCS.
- the MAC header includes fields of Frame Control, Duration, Address, Sequence Control, and HT (High Throughput) control. However, a frame format that does not include the HT Control field may be used.
- the Address field actually includes a plurality of fields such as an RA (Receiving Address) field for storing the MAC address of the destination terminal and a TA (Transmitting Address) field for storing the MAC address of the transmission source terminal.
- information to be inserted into the frame body is managed as an information element in Element ID units.
- the information element is identified by an Element ID, and has an Element ID field, a Length field, and an Information field.
- An Information field (hereinafter referred to as an information field) stores the content of information to be notified, and a Length field stores length information of the information field.
- One or more information elements can be stored in the frame body.
- use request channel information according to the present embodiment is also notified as an information element in the management frame.
- an information element name for example, a channel range element (Channel Range Element) is defined, and in this embodiment, when notifying use request channel information, this channel range element is used.
- 5A and 5B show examples of channel range element formats, respectively.
- the minimum channel number Minimum Channel Number
- channel width information Channel Band Information
- the minimum channel number Channel Number (Lower)
- the maximum channel number Channel Number (Upper)
- FIG. 6 shows the flow of the association process between the base station 101 and the terminals 201 to 203.
- Each terminal receives a beacon frame signal periodically transmitted from the base station 101 (S101), and performs a channel search of channels supported by the base station 101 (S102, S103, S104). Through the channel search, each terminal recognizes that the base station 101 supports channels 1-8.
- Terminal 202 determines channels 1 and 2 as usage request channels by carrier sense, and transmits an association request frame including usage request channel information to base station 101 in order to request base station 101 to allocate the usage request channel. (S105).
- the channels 1 and 2 are designated, and for example, the minimum channel number is 1 and the channel width information (number or bandwidth) is 2 or 40 MHz. Alternatively, the minimum channel number is 1 and the maximum channel number is 2.
- the base station 101 that has received the association request frame from the terminal 202 assigns channels 1 and 2 to the terminal 202.
- the base station 101 transmits an association response frame including allocation information specifying channel numbers 1 and 2 as allocation channels to the terminal 202 (S106).
- the minimum channel number is 1 and the channel width information (number or bandwidth) is 2 or 40 MHz.
- the minimum channel number is 1 and the maximum channel number is 2.
- the terminal 202 receives the association response frame transmitted from the base station 101, and recognizes that channels 1 and 2 have been allocated to its own terminal by confirming the allocation information in the response frame. Thereafter, the terminal 202 performs standby operation including carrier sense, signal reception, and signal transmission on channels 1 and 2 (S107).
- the terminal 201 decides to request the base station 101 to assign channel numbers 6, 7, and 8 by carrier sense, and transmits an association request frame including use request channel information specifying channel numbers 6 to 8. (S108).
- the usage request channel information for example, the minimum channel number is 6 and the channel width information (number or bandwidth) is 3 or 60 MHz. Alternatively, the minimum channel number is 6 and the maximum channel number is 8.
- the base station 101 that has received the association request frame from the terminal 201 assigns channels 6 to 8 to the terminal 201.
- the base station 101 transmits an association response frame including allocation information specifying channel numbers 6 to 8 as an allocation channel to the terminal 201 (S109).
- the allocation information for example, the minimum channel number is 6 and the channel width information (number or bandwidth) is 3 or 60 MHz.
- the minimum channel number is 6 and the maximum channel number is 8.
- the terminal 201 receives the association response frame transmitted from the base station 101, and confirms that the channels 6 to 8 are allocated to the own terminal by checking the allocation information in the response frame. Thereafter, terminal 201 performs standby operation including carrier sense, signal reception, and signal transmission on channels 6-8.
- data to be transmitted to the terminals 201 and 202 is generated in the base station 101, and the base station 101 transmits the RTS frame to the terminals 201 and 202 simultaneously on the respective standby channels in order to acquire the transmission right.
- Each of the terminals 201 and 202 receives the RTS frame on each standby channel, can normally receive the RTS frame on any channel, and / or determines that the carrier sense has been idle for a certain period before reception, Returns a CTS frame on the channel.
- the base station 101 that has received the CTS frame from the terminals 201 and 202 on each channel acquires the transmission right on each standby channel for the terminals 201 and 202.
- the base station 101 transmits data frames including transmission data for the terminals 201 and 202 to the terminals 201 and 202 simultaneously through the respective standby channels.
- the terminals 201 and 202 normally receive the data frame on each channel, and return an ACK frame indicating that the data frame has been normally received on each channel after SIFS from the reception of the data frame (S111a and S111b).
- channels 1 and 2 are used for communication with the terminal 202
- channels 6 to 8 are used for communication with the terminal 201. If there is a channel in which the terminal could not receive the RTS frame and / or a channel that could receive the RTS frame but was busy (CCA or NAV) for a certain period before reception, that channel Then, it is not necessary to return a CTS frame. In this case, the base station 101 does not transmit a data frame on that channel.
- the terminal 203 decides to request the base station 101 to assign channel numbers 1, 2, 3, and 4 by carrier sense, and an association request frame including use request channel information specifying channel numbers 1 to 4 Send.
- the usage request channel information for example, the minimum channel number is 1, and the channel width information (number or bandwidth) is 4 or 80 MHz. Alternatively, the minimum channel number is 1 and the maximum channel number is 4. Since base station 101 has already set channels 1 and 2 to terminal 201, channel 1 and channel 2 cannot be assigned to terminal 203, but channels 3 and 4 have not yet been assigned to any terminal. Judge that it is possible. For this reason, the base station 101 assigns only the channels 3 and 4 to the terminal 203. The base station 101 transmits an association response frame including allocation information that specifies channel numbers 3 and 4 as allocation channels.
- the minimum channel number is 3, and the channel width information (number or bandwidth) is 2 or 40 MHz.
- the minimum channel number is 3 and the maximum channel number is 4.
- the terminal 203 receives the association response frame transmitted from the base station 101 and confirms the allocation information in the response frame, thereby recognizing that channels 3 and 4 are allocated to the terminal. Thereafter, the terminal 203 performs a standby operation including carrier sense, signal reception, and signal transmission on the channels 3 and 4.
- the base station 101 In the base station 101, data to be transmitted to the terminals 201, 202, and 203 is generated, and the base station 101 transmits the RTS frame to the terminals 201, 202, and 203 simultaneously on the respective standby channels in order to acquire the transmission right.
- the CTR frame is returned from each of the terminals 201, 202, and 203, whereby the base station 101 acquires the transmission right for each of the standby channels for the terminals 201, 202, and 203.
- the base station 101 transmits data frames including transmission data for the terminals 201, 202, and 203 to the terminals 201, 202, and 203 simultaneously on the respective standby channels, and the data frames from the terminals 201, 202, and 203 are normal.
- An ACK frame indicating that it has been received is returned on each channel (S115a, S115b, S115c).
- channels 1 and 2 are used for communication with the terminal 202
- channels 6 to 8 are used for communication with the terminal 201
- channels 3 and 4 are used for communication with the terminal 203.
- the base station 101 assigns channels to each terminal so as not to overlap, but the base station 101 assigns all the channels requested by the terminal to the terminal and actually transmits data.
- the channels may be selected so that the channels to be used do not overlap between terminals.
- the base station 101 allocates all the channels 1 to 4 requested to be allocated to the terminal 203, and transmits allocation information specifying the channels 1 to 4 in an association response frame.
- the channels to be used are selected so as not to overlap each other. For example, channel 1 of channels 1 and 2 assigned to terminal 202 and channels 2 to 4 of channels 1 to 4 assigned to terminal 203 are used for transmission to terminals 202 and 203.
- the number of channels to be used for the terminals 202 and 203 may be determined according to the amount of data to be transmitted, and the channel may be selected accordingly, or the channel quality is measured for each terminal.
- the channel to be used may be selected. You may select by methods other than what was described here.
- the plurality of frames to be transmitted may be the same or different.
- a base station transmits or receives a plurality of frames or a plurality of Xth frames these frames or the Xth frames may be the same or different.
- X can be set to any value depending on the situation.
- FIG. 7 is a flowchart showing the operation of the terminal according to the present embodiment.
- the terminal carrier senses a plurality of channels within a predetermined frequency band supported by the base station 101 (S201), and determines one or more channels for which allocation is requested (S202). As an example, a plurality of channels are determined so as to select consecutive channels.
- the terminal transmits an association request frame including use request channel information for requesting allocation of the selected channel to the base station 101 (S203).
- the use request channel information includes the smallest or largest channel number among consecutive channels and channel width information for specifying the number of channels or bandwidth for which allocation is requested. Contains at least one set. Or, it includes at least one set of the lowest channel number of consecutive channels and the largest channel number.
- the use request channel information is included in the association request frame, but it is also possible to transmit it by including it in a reassociation request frame or other management frame (for example, a newly defined management frame).
- the terminal receives from the base station 101 an association response frame including allocation information specifying one or more channels allocated by the base station 101 (S204).
- the terminal extracts allocation information from the association response frame, and communicates with the base station by transmitting and receiving a frame with the base station through a channel specified by the allocation information (S205). For example, the terminal simultaneously performs downlink reception or uplink transmission with respect to the base station 101 using different channels together with other terminals.
- FIG. 8 is a flowchart showing the operation of the base station 101 according to this embodiment.
- the base station 101 receives an association request frame including use request channel information from each terminal (S301).
- the base station 101 allocates one or more channels to each terminal based on the usage request channel information received from each terminal (S302). As an example, when assigning a plurality of channels to a terminal, continuous channels are selected.
- the base station 101 generates an association response frame including allocation information specifying the channel allocated to each terminal, and transmits it to each terminal (S303).
- the allocation information may have the same format as the usage request channel information, for example. In other words, when a plurality of consecutive channels are allocated to the terminal, the allocation is performed by at least one set of the smallest or largest channel number among the consecutive channels and the channel width information specifying the allocated channel number or bandwidth. Configure information. Alternatively, the allocation information is configured by at least one set of the lowest channel number of consecutive channels and the largest channel number.
- the association response frame is transmitted including the allocation information, it is also possible to transmit it in a reassociation response frame, a beacon frame, or other management frame (for example, a newly defined management frame).
- the base station 101 communicates with each terminal by transmitting and receiving frames to and from each terminal using a channel assigned to each terminal (S304). For example, the base station 101 performs downlink transmission or uplink reception at the same time using different channels from each terminal.
- the base station allocates a desired channel to each terminal in advance, and each terminal performs subsequent standby using only the allocated channel, that is, the minimum necessary channel.
- the base station communicates simultaneously with each terminal using a channel assigned to each terminal. Therefore, the number of terminals communicating simultaneously can be increased, and all channels can be used effectively, compared to the prior art in which channels are allocated and communicated so that one terminal is sequentially expanded from the primary channel. Thereby, the utilization efficiency of the whole channel can be improved.
- the terminal 201 determines a use request channel among the channels served by the base station 101 by carrier sense, and inserts the information into the association request frame.
- the association request frame includes reason information indicating the reason for determining the use request channel together with use request channel information.
- a reason code (Reason code) defined in the IEEE 802.11 specification is used as the reason information form. The reason code is expressed numerically and is associated with a predefined reason.
- the reason already defined in the IEEE 802.11 specification is “Previous” authentication no longer valid "," 4-Way Handshake timeout ", etc.
- an association request frame is not defined as a candidate frame into which a reason code is inserted.
- the reason code of the reason for selecting the use request channel is inserted into the frame body field of the association request frame, and the base station shall assign an appropriate channel by each terminal by considering the reason code notified from the terminal. Is possible.
- the reason for selecting the use request channel is “select channel because other channels are busy” (channel select because other channels are busy) or “channel selected, but other channels may cause interference. It does not have to be "(Channel select but not adher them). However, even if it is a candidate other than this, if there is a valid reason used by the base station for channel assignment determination, the reason may be defined as the reason code.
- 2 octets are prepared as a reason code field, and a number (reason code) associated with the reason is notified in the reason code field.
- Numbers 1 to 66 have already been used, and numbers 67 and after are currently unused as reserved (Reserve). Therefore, for example, 67 is defined as “select channel because other channels are busy” (channel select because other channels are busy), and 68 is defined as “channel selected but other channels” However, it does not have to be interference ”(Channel select but not adhere them).
- the number to be used may be arbitrary as long as the correspondence with the reason is taken.
- the base station 101 When the base station 101 receives an association request frame including a reason code from the terminal, the base station 101 performs channel allocation in consideration of the reason code. As a result, appropriate channel allocation becomes possible, channel availability can be increased, and channel utilization efficiency can be increased.
- FIG. 9 shows the configuration of the wireless communication system according to the present embodiment.
- a wireless communication group in which the base station 102 and the terminal 301 are interconnected is shown.
- the coverage areas formed by the base station 101 and the base station 102 partially overlap, and the terminal 201 connected to the base station 101 is located in the overlapping area.
- FIG. 10 shows a flow of an association process in the base station 101 and terminals 201 to 203 according to the present embodiment.
- the description of the same parts as in FIG. 6 is omitted.
- the main points different from the flow of FIG. 6 are indicated by the use request channel information in addition to the use request channel information in the frame body of the association request frame transmitted from the terminals 201 and 203 to the base station 101 in steps S108 and S112.
- a reason code indicating the reason for selecting the channel is included.
- the terminal 201 detects a signal transmitted / received between the base station 102 and the terminal 301 of another wireless communication system as busy in the carrier sense before transmitting the association request frame in step S108.
- transmission / reception is performed between the base station 102 and the terminal 301 using the channels 1 to 4, and the terminal 201 detects the channels 1 to 4 as busy.
- the terminal 201 includes a reason code indicating that another channel is busy in addition to use request channel information specifying channels 6 to 8.
- the reason code here is, for example, reason code 67 (the other channels are busy) because the result of carrier sense is that channels 1 to 4 are busy.
- the base station 101 determines that it is difficult to allocate channels other than the channels 6 to 8 to the terminal 201. Channels 6 to 8 are not assigned to any terminal at this time, and no assignment request has been received from other terminals. Therefore, it is determined that the requested channels 6 to 8 can be assigned to the terminal 201. .
- the base station 101 allocates the channels 6 to 8 to the terminal 201 and returns an association response frame including allocation information designating the channels 6 to 8 to the terminal 201 (S109).
- step S112 the terminal 203 selects channels 1 to 4 as the use request channels without any particularly busy channels in the carrier sense before transmitting the association request frame.
- the terminal 203 transmits, in the association request frame to be transmitted to the base station 101, an association request frame including a reason code 68 indicating that other channels may be used in addition to use request channel information specifying channels 1 to 4.
- the channels 3 to 4 can be assigned to the terminal 202, but the channels 1 to 2 are already assigned to the terminal 202 and are determined not to be assigned to the terminal 203. .
- the base station 101 assigns channel 5 to terminal 203 together with channels 3 and 4.
- the base station 101 returns an association response frame including allocation information specifying channels 3 to 5 as allocation channels to the terminal 203 (S113).
- a reason code indicating the reason for allocating the channel may be included similarly to the association request frame. For example, since part or all of the requested channel could not be allocated, a reason code indicating that another channel was allocated is defined as number 69, and the association response is returned from the base station 101 to the terminal 203 in step S113.
- a reason code number 69 may be included in the frame.
- the base station supports determination when allocating a channel to each terminal by including the reason code for notifying the reason why each terminal has selected the channel in the association request frame. As a result, appropriate channel allocation becomes possible.
- a plurality of channels supported by the base station are arbitrarily allocated to a plurality of terminals, and each terminal basically operates in a standby mode on the allocated channels. I should have done.
- each terminal in addition to the assigned channel, each terminal can transmit at least the primary channel. Standby operation is required. In this case, the number of channels that perform the standby operation increases compared to the case where the standby operation is performed only on the assigned channel, leading to an increase in power consumption of the terminal.
- the base station transmits the same beacon frame on each supported channel. Transmitting the same frame on a plurality of channels is called Duplicate transmission.
- the base station 101 transmits transmission capability information and reception capability information indicating which channel can transmit and receive, primary channel information specifying which channel the primary channel is, or both of the primary channel or another channel. Transmit by beacon frame on channel or both.
- Each terminal determines whether a beacon frame is Duplicate transmitted on each channel supported by the base station from the transmission capability information of the base station. If it is determined that a beacon frame is transmitted in duplicate on each channel, the terminal can determine that it is not necessary to perform a standby operation on the primary channel. In this case, the terminal may perform a standby operation using only the channel assigned by the base station.
- the terminal determines whether the channel that is transmitted in Duplicate is included in the channel allocated to the terminal itself. If the channel allocated to the terminal includes a channel to be transmitted by Duplicate, the standby operation may be performed using only the allocated channel. Otherwise, it is necessary to perform standby operation even on the primary channel.
- the base station notifies the transmission / reception capability of each channel using a notification frame such as a beacon frame, and Duplicate transmission of the beacon frame makes it possible for each terminal to reduce the number of channels that perform standby operations. Become. Thereby, power consumption can be reduced.
- a notification frame such as a beacon frame
- the terminal performs a standby operation on all the channels allocated from the base station, and in the third embodiment, in addition to the channel, if necessary, the primary channel of the system However, the standby operation was performed.
- the beacon frame when the beacon frame is transmitted from the base station in duplicate, the contents of the beacon frame received by each channel are the same, so the standby operation (including carrier sense) in some channels, for example, one channel, and It is also possible to perform a signal receiving operation.
- This also applies to not only a beacon frame but also a RTS frame or a control frame having a similar function transmitted from the base station in a Duplicate manner on each channel.
- standby and signal reception operations are performed on only one channel or a part of the channels allocated from the base station at the time of initial connection, and only carrier sense is performed on the other allocated channels. Do. Further, if the standby channel is determined in advance as one or a part of the channel between the base station and the terminal, the base station transmits the control frame or the like in the one or part of the standby channel. It does not matter even if it is only transmitted.
- the terminal side receives an RTS frame or a control frame having an equivalent function on one or a part of the assigned channels (carrier sensing is performed on all channels), and receives a CTS frame or a control frame having a similar function. Return on all channels that were idle in career sense. Then, the standby operation is performed on all the assigned channels whose carrier sense is idle, and the reception of the data frame is awaited.
- the base station transmits data frames on all channels or parts of CTS frames that have been returned.
- the terminal can select and use one or a part of the channels for performing the standby operation from the channels allocated from the base station, thereby reducing power consumption during standby.
- the base station 101 performs transmission and reception separately in time. That is, the base station 101 is assumed to perform either transmission or reception simultaneously on each channel. It has not been assumed that reception or transmission timing is different for each channel, or transmission and reception are mixed between channels.
- the base station may be equipped with a mechanism called so-called full duplex, which can cope with a mixture of transmission and reception.
- full duplex there is no restriction on the terminal side to perform transmission and reception at the same timing as other terminals. Therefore, in this case, when the terminal detects that the carrier sense is idle for a certain period of time for the use request channel, the terminal may transmit / receive a management frame such as an association request frame in all or a part of the channel. Is possible.
- information indicating whether or not the base station is full duplex is included in a capability field (Capability) field of a beacon frame transmitted from the base station.
- This information is, for example, 1 bit, and it may be determined in advance that bit 1 corresponds to full duplex and bit 0 corresponds to non-correspondence. Of course, the reverse bit association may be performed.
- the terminal determines whether the base station supports full duplex or not.
- each terminal transmits / receives an association-related frame (association request frame, association response frame, etc.) on all or a part of the selected use request channels.
- association request frame association request frame
- association response frame association response frame
- the base station when the base station does not support full duplex, at least the association-related frame is transmitted through a channel including at least a primary channel common to the system. In this case, it is desirable to be able to grasp busy / idle on the assumption that all terminals monitor on the primary channel.
- the base station may preferentially assign the primary channel when assigning channels. As a result, when the base station is not supporting full-duplex and is simultaneously communicating with a plurality of terminals through a plurality of channels, if the other terminal monitors the primary channel, it detects a busy state and detects an association-related frame. Can be prevented.
- the base station is communicating with multiple terminals simultaneously on multiple channels that do not include the primary channel, and the other terminal determines that the primary channel is idle and transmits an association-related frame
- the base station Depending on the reception timing of the frame, the association-related frame may not be normally received depending on the performance. This is not limited to association-related frames, but is the same for other frames.
- the base station notifies the terminal whether or not full duplex is supported, so that the association process can be performed using a channel other than the primary channel.
- Each terminal can communicate with the base station at a timing independent of other terminals using one or a plurality of channels allocated from the base station.
- FIG. 11 shows a configuration of a wireless communication system provided with a base station and a terminal according to the present embodiment.
- a wireless communication group in which the base station 103 and the terminal 401 are interconnected is shown.
- the coverage areas formed by the base station 103 and the base station 101 partially overlap, and the terminals 201 and 203 connected to the base station 101 are located in the overlapping areas.
- the terminal 401 desiring to connect to the base station 103 determines that interference exists in the channels 3 to 6 from the carrier sense result, and selects the use request channel from the other channels.
- the choice of the terminal 401 is up to 2 channels if a continuous channel is desired, and up to 4 channels if it is not necessary to be a continuous channel. Which one is actually selected depends on the processing capability of the PHY processing unit and the radio unit 20, the required transmission rate determined by a request from the application, and the like. In the following, a method for notifying the selected channel to the base station 101 when the terminal 401 selects a plurality of channels that are not continuous as usage request channels will be described.
- FIG. 12 shows a format example of a channel range element according to the present embodiment.
- the channel range element is included in management frames such as association request frames and association response frames.
- an information field includes a minimum channel number (Minimum Channel Number) and channel width information (Channel Band). Include a set of Information or a set of minimum channel number (Channel Number (Lower)) and maximum channel number (Channel Number (Upper)). However, when a plurality of non-consecutive channels are requested as in this embodiment, a plurality of such sets are included in the information field.
- a set of minimum channel number 1 and maximum channel number 2 and a set of minimum channel number 8 and maximum channel number 8 are set in the information field.
- the Length field is also designated with a length corresponding thereto, so that the receiving side can understand that a plurality of sets are included.
- each terminal does not make a channel use request, but makes a resource block use request.
- each terminal determines the status of each resource block in determining which resource block to use. For example, based on the received power of the signal of each resource block received from the base station, a resource block (usage request resource block) that makes a use request may be preferentially selected from resource blocks with high received power.
- Each terminal notifies the base station of information (use request resource block information) specifying the selected use request resource block. The base station determines a resource block to be allocated to the terminal from among the resource blocks specified by the information, and allocates the determined resource block to the terminal.
- a predetermined number (for example, one) of resource blocks may be allocated to the terminal, or all or less resource blocks requested by the terminal may be allocated to the terminal according to the resource block allocation status. You may do it.
- the base station transmits allocation information specifying the resource block allocated to the terminal to the terminal.
- the allocation information may be notified using a SIGNAL field of a physical header related to a data frame multiplexed and transmitted by OFDMA, instead of transmitting the allocation information in a frame in advance before OFDMA communication.
- carrier sense is performed in units of channels as in the previous embodiments, and if one channel is busy, it may be determined that all resource blocks belonging to that channel are busy. . However, it is also possible to configure so that carrier sense is performed in units of resource blocks.
- the frame for measuring the received power by the terminal may be an arbitrary frame transmitted by the base station. It may be a beacon frame, another management frame, a control frame, a data frame, or all of these.
- the received power may be measured by using a predetermined field (a field whose bits are known) of the preamble of the physical header.
- the base station may transmit a frame for each resource block, and the terminal may measure the received power using the physical header of each frame.
- the received power may be SINR, SNR, or other index.
- the determination may be based on MCS instead of reception power.
- the resource block may be preferentially selected from resource blocks in which the terminal can use the MCS having the highest transmission rate.
- a part of the top side of the physical header transmits a common part using the entire bandwidth of one channel width, and a part of the head side You may transmit a separate thing for every resource block from the back.
- a part of the frame portion to be transmitted for each resource block on the back side may be used as a field for storing a known bit string, and reception power may be measured using this field.
- a management frame such as an association request frame or a newly defined management frame may be used as in the previous embodiments.
- an information element including use request resource block information may be set in the frame body field of the management frame.
- the format of the information element may be determined according to the format shown in FIG.
- use request resource block information can be set in an arbitrary field of a physical header of a data frame or a control frame or both of them instead of a newly defined management frame.
- Examples of the control frame include an RTS frame, a CTS frame, and an ACK frame.
- FIG. 21B A format example of the usage request resource block information is shown in FIG.
- the presence / absence of resource block designation (use request) is expressed in bits, and fields corresponding to the number of bits of the number of resource blocks existing in one channel are provided.
- four fields are provided. If a resource block is specified, “1” is set in the corresponding field, otherwise “0” is set.
- resource blocks 1 and 2 are specified and resource blocks 3 and 4 are not specified, the values of the resource block 1 information field to resource block 4 information field are set to 1, 1, 0, and 0, respectively.
- the same format as shown in FIG. 21B may be arranged for the number of channels (here, the number of channels is N). In the case of FIG. 21B, the channel requesting use and the resource block requesting use in the use request channel are designated.
- FIG. 22 schematically shows the configuration of a physical packet including a physical header and a MAC frame.
- L-STF, L-LTF, and L-SIG are arranged at the beginning of the physical header, and a new field is provided behind the MAC frame (or an existing field).
- Use request resource block information may be set in a part or all of the field.
- L is a legacy field.
- Information such as signal detection, frequency correction, and transmission speed are stored.
- the data frame or control frame for notifying the use request resource block information may be a frame transmitted in normal communication (communication on one channel) when OFDMA communication is not performed, or using a resource block during OFDMA communication. It may be a frame to be transmitted. In addition, if one channel width is 20 MHz, a part of the head side of a frame transmitted from each terminal to the base station at the time of OFDMA communication is transmitted in a band of 20 MHz for each terminal, and the part after that is the terminal Each resource block may be transmitted. At this time, some contents on the head side may be common to each terminal.
- a part of the head side includes, as an example, fields of L-STF, L-LTF, and L-SIG, and a field (Between the L-SIG and the MAC frame) arranged behind the field. Part of the field).
- the above-described new preamble field may be included in a part on the head side or may be included in a field on the rear side.
- the present embodiment can be implemented by replacing the channels of the first to sixth embodiments and the eighth and subsequent embodiments with resource blocks. Variations or expansions or both are possible.
- “channel” can be read as “resource block”, “channel width information” as “resource block width information”, and “channel number” as “resource block number”.
- the standby operation is also performed on the channel.
- a predetermined channel such as a primary channel
- the standby operation is also performed on the predetermined channel. This may be read as follows. In other words, when the resource block specified by the allocation information does not belong to a predetermined channel, the standby operation is also performed on the predetermined channel (assuming that carrier sense is performed in units of channels).
- a frame is waited for and received on a part of the channel specified by the allocation information, and carrier sense is performed on the other channels for standby.
- the CTS frame was transmitted by the received channel and the channel that was idle by the carrier sense.
- Frame waiting and signal reception are performed in some resource blocks of the resource block specified by the allocation information, and carrier sense is performed in other resource blocks. Then, when the RTS frame is received by the waiting resource block, the CTS frame is transmitted by the resource block that is idle by carrier sense and the resource block that has received the RTS frame.
- the embodiments can be configured by appropriately replacing various portions of the embodiments.
- a channel is assigned to a terminal in the exchange of an association-related frame at the time of initial connection, and the channel is continuously used thereafter.
- a suitable channel is changed from the initially determined channel due to a change in the channel condition thereafter. Therefore, an embodiment will be described in which the channel used is changed during connection according to the channel status.
- a reassociation request frame and a reassociation response frame already defined in the IEEE 802.11 specification can be used as a frame used to change the channel used.
- request frames and response frames using the same Element ID as the channel range element (Channel Range Element) described in the first to fourth embodiments, use request channel information specifying a channel to be newly used and It is conceivable to notify the allocation information specifying the newly allocated channel.
- the frame types of the reassociation request frame and the reassociation response frame are different from those of the association request frame and the association response frame, the channel range element stored in the frame body may be of the same type as that in FIGS.
- FIG. 13 shows a format example of the state change frame.
- a set of minimum channel number Minimum Channel Number
- channel width information Channel Band Information
- a set of minimum channel number Chower
- maximum channel number Choannel Number (Upper)
- formats other than those shown here may be used.
- the contents of the frame header may be other than those shown in the figure.
- the present embodiment it is possible to effectively use the channel by updating the used channel according to the channel state not only during the initial connection but also during the connection.
- the maximum number of channels in the predetermined frequency band is channels 1 to 8. These channels are assumed to be continuous. Supplementary explanation will be given for the continuity of these channels.
- the channel numbers in the IEEE 802.11 standard are 5 MHz intervals, and when the channel width is 20 MHz, the intervals of channel numbers that do not cover each other are every four channels.
- the continuous channel in the channel set in this specification is described as meaning a continuous channel that does not cover each other.
- the channel number in the specification is for convenience. 1 is a channel number 36 of 5 GHz band in the IEEE 802.11 standard, ch. 2 may be interpreted as a channel number 40 of 5 GHz band in the IEEE 802.11 standard.
- [5 GHz band] In the 5 GHz band according to the IEEE 802.11 standard, channel numbers are basically used at 20 MHz intervals, so there is no problem considering the channel numbers being used.
- ch. 1 is a channel number 1 in the 2.4 GHz band in the IEEE 802.11 standard
- ch. 2 may be set at 25 MHz intervals (FIG. 14A) following North America and China, such as 2.4 GHz band channel number 6 in the IEEE 802.11 standard.
- ch. 1 is a channel number 1 in the 2.4 GHz band in the IEEE 802.11 standard, ch.
- FIG. 14C illustrates channel selection that will be considered in the future in addition to FIGS. 14A and 14B.
- channel numbers 6 and 7 in the 2.4 GHz band as at least some channels
- channel numbers 5 and some frequencies Bandwidth will suffer.
- the frequency band affected by each other's wireless communication system is expanded, and the channel utilization efficiency is lowered.
- FIG. 15 shows an example of a hardware configuration of a wireless communication device mounted on a terminal according to the embodiment of the present invention.
- This hardware configuration is an example, and the hardware configuration can be variously changed.
- the operation of the wireless communication apparatus shown in FIG. 15 is the same as that of the terminal wireless communication apparatus described above with reference to FIG. Is omitted.
- This wireless communication apparatus includes a baseband unit 111, an RF unit 121, and antennas 1 to N.
- the baseband unit 111 includes a control circuit 112, a transmission processing circuit 113, a reception processing circuit 114, DA conversion circuits 115 and 116, and AD conversion circuits 117 and 118.
- the RF unit 121 and the baseband unit 111 may be configured as a single chip IC (Integrated Circuit) or may be configured as separate chips.
- the baseband unit 111 is a baseband LSI, a baseband IC, or both.
- the baseband unit 111 may include an IC 132 and an IC 131 as indicated by a dotted frame shown in the figure.
- the IC 132 may include the control circuit 112, the transmission processing circuit 113, and the reception processing circuit 114, and the IC 131 may be divided into the respective ICs so as to include the DA conversion circuits 115 and 116 and the AD conversion circuits 117 and 118. .
- the control circuit 112 corresponds to, for example, a communication processing device that controls communication or a control unit that controls communication.
- the communication processing device or the control unit may further include at least one of the transmission processing circuit 113 and the reception processing circuit 114.
- the wireless communication unit may include a transmission processing circuit 113 and a reception processing circuit 114.
- the wireless communication unit may include DA conversion circuits 115 and 116 and AD conversion circuits 117 and 118 in addition to the transmission processing circuit 113 and the reception processing circuit 114.
- the wireless communication unit may include a transmission circuit 122 and a reception circuit 123 in addition to the transmission processing circuit 113, the reception processing circuit 114, the DA conversion circuits 115 and 116, and the AD conversion circuits 117 and 118.
- the integrated circuit includes all or part of the processing of the baseband unit 111, that is, the control circuit 112, the transmission processing circuit 113, the reception processing circuit 114, the DA conversion circuits 115 and 116, and the AD conversion circuits 117 and 118.
- a processor that performs all or part of the processing may be provided.
- the IC 132 may correspond to a communication processing device that controls communication.
- the wireless communication unit may include a transmission circuit 122 and a reception circuit 123. Further, the wireless communication unit may include DA conversion circuits 115 and 116 and AD conversion circuits 117 and 118 in addition to the transmission circuit 122 and the reception circuit 123.
- the control circuit 112 mainly executes the functions of the access control unit 33, the control unit 34, the transmission unit 31, and the reception unit 32.
- the function of the upper layer processing unit 40 may be included in the control circuit 112.
- the control circuit 112 may include a clock generation unit.
- the transmission processing circuit 113 corresponds to a part that performs physical layer processing of each transmission / reception processing unit of the PHY processing unit and the wireless unit 20 illustrated in FIG. 2. That is, the transmission processing circuit 113 performs processing such as addition of a preamble and a PHY header, encoding, and modulation.
- the reception processing circuit 114 corresponds to a part that performs reception processing of the physical layer of each transmission / reception processing unit of the PHY processing unit and the wireless unit 20 illustrated in FIG. 2.
- the transmission processing circuit 113 performs processing such as demodulation, decoding, preamble and PHY header analysis, and generates, for example, two types of digital baseband signals (hereinafter, digital I signal and digital Q signal). 2 may be included in the transmission processing circuit 113, the reception unit 32 may be included in the reception processing circuit 114, and the functions of the access control unit 33 and the control unit 34 may be included in the control circuit 112. It is.
- the communication processing apparatus of the present embodiment corresponds to, for example, the control circuit 112 and may further include at least one of a transmission processing circuit 113 and a reception processing circuit 114.
- the communication processing apparatus according to the present embodiment includes both a one-chip IC form and a plurality of chip IC forms.
- the DA conversion circuits 115 and 116 correspond to portions that perform DA conversion of each transmission / reception processing unit shown in FIG.
- the DA conversion circuits 115 and 116 DA convert the frames processed by the transmission processing circuit 113. More specifically, the DA conversion circuit 115 converts the digital I signal into an analog I signal, and the DA conversion circuit 116 converts the digital Q signal into an analog Q signal. Note that there may be a case where the signal is transmitted as it is without a quadrature modulation. In this case, only one DA conversion circuit may be provided. Further, in the case where one or a plurality of transmission signals are distributed and transmitted by the number of antennas, a number of DA conversion circuits corresponding to the number of antennas may be provided.
- the RF unit 121 is, for example, an RF analog IC, a high frequency IC, or both.
- the transmission circuit 122 in the RF unit 121 corresponds to a part that performs analog processing during transmission at a stage after DA conversion in each of the transmission / reception processing units illustrated in FIG.
- the transmission circuit 122 uses a transmission filter that extracts a signal in a desired band from the signals of the D / A converted frames by the D / A conversion circuits 115 and 116, and a signal having a constant frequency supplied from the oscillation device, and outputs the filtered signal. It includes a mixer that upconverts to a radio frequency, a preamplifier (PA) that amplifies the signal after upconversion, and the like.
- PA preamplifier
- the reception circuit 123 in the RF unit 121 corresponds to a part that performs analog processing at the time of reception up to the stage before AD conversion in each transmission / reception processing unit shown in FIG.
- the receiving circuit 123 includes an LNA (low noise amplifier) that amplifies the signal received by the antenna, a mixer that downconverts the amplified signal to baseband using a signal of a constant frequency supplied from the oscillation device, A reception filter that extracts a signal in a desired band from the signal after the conversion is included.
- LNA low noise amplifier
- the reception circuit 123 performs quadrature demodulation on a reception signal amplified by a low-noise amplifier (not shown) using a carrier wave that is 90 ° out of phase with each other to obtain I (In-phase) in-phase with the reception signal. ) Signal and a Q (Quad-phase) signal whose phase is delayed by 90 ° therefrom. These I and Q signals are output from the receiving circuit 123 after the gain is adjusted.
- the control circuit 112 may control the operations of the transmission filter of the transmission circuit 122 and the reception filter of the reception circuit 123 so as to extract the signal of the channel covered by the channel according to the setting of the channel to be used. There may be another control unit that controls the transmission circuit 122 and the reception circuit 123, and the control circuit 112 may perform similar control by giving an instruction to the control unit.
- the AD conversion circuits 117 and 118 in the baseband unit 111 correspond to a part that performs AD conversion of each transmission / reception processing unit shown in FIG.
- the AD conversion circuits 117 and 118 AD convert the input signal from the reception circuit 123. More specifically, the AD conversion circuit 117 converts the I signal into a digital I signal, and the AD conversion circuit 118 converts the Q signal into a digital Q signal. There may be a case where only one system signal is received without performing quadrature demodulation. In this case, only one AD conversion circuit is required. In the case where a plurality of antennas are provided, the number of AD conversion circuits corresponding to the number of antennas may be provided.
- the control circuit 112 also performs processing related to MIMO, for example, propagation path estimation processing, transmission weight calculation processing, and stream separation processing.
- a switch for switching the antennas 1 to N to either the transmission circuit 122 or the reception circuit 123 may be arranged in the RF unit. By controlling the switch, the antennas 1 to N may be connected to the transmission circuit 122 during transmission, and the antennas 1 to N may be connected to the reception circuit 123 during reception.
- the DA conversion circuits 115 and 116 and the AD conversion circuits 117 and 118 are disposed on the baseband unit 111 side, but may be configured to be disposed on the RF unit 121 side.
- the transmission circuit 122 and the reception circuit 123 may form a wireless communication unit.
- the transmission circuit 122 and the reception circuit 123 may further include DA conversion circuits 115 and 116 and AD conversion circuits 117 and 118 to form a wireless communication unit.
- a wireless communication unit may be formed including the PHY processing parts of the transmission processing circuit 113 and the reception processing circuit 114.
- the wireless communication unit may be formed by the PHY reception processing part of the transmission processing circuit 113 and the reception processing circuit 114.
- FIG. 16 shows an example of a hardware configuration of a wireless communication apparatus mounted on the base station according to the embodiment of the present invention.
- This hardware configuration is an example, and the hardware configuration can be variously changed. Since the operation of the wireless communication apparatus shown in FIG. 16 is the same as that of the base station wireless communication apparatus described above with reference to FIG. 3, the following description will focus on differences in hardware configuration, and detailed operations will be described. Description is omitted.
- the wireless communication apparatus includes a baseband unit 211, an RF unit 221, and antennas 1 to N.
- the baseband unit 211 includes a control circuit 212, a transmission processing circuit 213, a reception processing circuit 214, DA conversion circuits 215 and 216, and AD conversion circuits 217 and 218.
- the RF unit 221 and the baseband unit 211 may be configured as a single chip IC (Integrated Circuit) or may be configured as separate chips.
- the baseband unit 211 is a baseband LSI, a baseband IC, or both.
- the baseband unit 211 may include an IC 232 and an IC 231 as indicated by the dotted frame in the figure.
- the IC 232 may be divided into each IC so that the IC 232 includes the control circuit 212, the transmission processing circuit 213, and the reception processing circuit 214, and the IC 231 includes the DA conversion circuits 215 and 216 and the AD conversion circuits 217 and 218. .
- the control circuit 212 corresponds to, for example, a communication processing device that controls communication or a control unit that controls communication.
- the communication processing device or the control unit may further include at least one of the transmission processing circuit 213 and the reception processing circuit 214.
- the wireless communication unit may include a transmission processing circuit 213 and a reception processing circuit 214.
- the wireless communication unit may include DA conversion circuits 215 and 216 and AD conversion circuits 217 and 218 in addition to the transmission processing circuit 213 and the reception processing circuit 214.
- the wireless communication unit may include a transmission circuit 222 and a reception circuit 223 in addition to the transmission processing circuit 213, the reception processing circuit 214, the DA conversion circuits 215 and 216, and the AD conversion circuits 217 and 218.
- the integrated circuit according to this embodiment includes all or part of the processing of the baseband unit 211, that is, the control circuit 212, the transmission processing circuit 213, the reception processing circuit 214, the DA conversion circuits 215 and 216, and the AD conversion circuits 217 and 218.
- a processor that performs all or part of the processing may be provided.
- the IC 232 may correspond to a communication processing device that controls communication.
- the wireless communication unit may include a transmission circuit 222 and a reception circuit 223. Further, the wireless communication unit may include DA conversion circuits 215 and 216 and DA conversion circuits 217 and 218 in addition to the transmission circuit 222 and the reception circuit 223.
- the control circuit 212 mainly executes the functions of the access control unit 83, the control unit 84, the transmission unit 81, and the reception unit 82.
- the function of the upper layer processing unit 90 may be included in the control circuit 212.
- the control circuit 212 may include a clock generation unit.
- the transmission processing circuit 213 corresponds to a part that performs physical layer processing of each of the transmission / reception processing units of the PHY processing unit and the wireless unit 70 illustrated in FIG. 3. That is, the transmission processing circuit 213 performs processing such as addition of a preamble and a PHY header, encoding, and modulation.
- the transmission processing circuit 213 performs processing such as addition, encoding, and modulation of a preamble and a PHY header, and generates, for example, two types of digital baseband signals (hereinafter, digital I signal and digital Q signal). In the case of MIMO transmission, two types of digital baseband signals are generated for each stream.
- the communication processing apparatus of this embodiment corresponds to, for example, the control circuit 212 and may further include at least one of a transmission processing circuit 213 and a reception processing circuit 214.
- the communication processing apparatus according to the present embodiment includes both a one-chip IC form and a plurality of chip IC forms.
- the DA conversion circuits 215 and 216 correspond to the DA conversion part of each transmission / reception processing unit shown in FIG.
- the DA conversion circuits 215 and 216 D / A convert the frame processed by the transmission processing circuit 213. More specifically, the DA conversion circuit 215 converts the digital I signal into an analog I signal, and the DA conversion circuit 216 converts the digital Q signal into an analog Q signal. Note that there may be a case where the signal is transmitted as it is without a quadrature modulation. In this case, only one DA conversion circuit may be provided. Further, in the case where one or a plurality of transmission signals are distributed and transmitted by the number of antennas, a number of DA conversion circuits corresponding to the number of antennas may be provided.
- the RF unit 221 is, for example, an RF analog IC or a high-frequency IC, or both.
- the transmission circuit 222 in the RF unit 221 corresponds to a part that performs analog processing during transmission at a stage after DA conversion in each of the transmission / reception processing units illustrated in FIG. 3.
- the transmission circuit 222 uses a transmission filter that extracts a signal in a desired band from the signal of the frame DA-converted by the DA conversion circuits 215 and 216, and a signal with a constant frequency supplied from the oscillation device, and then outputs the filtered signal. It includes a mixer that upconverts to a radio frequency, a preamplifier (PA) that amplifies the signal after upconversion, and the like.
- PA preamplifier
- the reception circuit 223 in the RF unit 221 corresponds to a part that performs analog processing at the time of reception up to a stage before AD conversion in each transmission / reception processing unit illustrated in FIG.
- the receiving circuit 223 uses an LNA (low noise amplifier) that amplifies the signal received by the antenna, a mixer that down-converts the amplified signal to baseband using a signal of a constant frequency supplied from the oscillation device, and down A reception filter that extracts a signal in a desired band from the signal after the conversion is included.
- LNA low noise amplifier
- the reception circuit 223 performs quadrature demodulation on the received signal amplified by a low-noise amplifier (not shown) using carrier waves that are 90 ° out of phase with each other, and receives I (In-phase) in-phase with the received signal. ) Signal and a Q (Quad-phase) signal whose phase is delayed by 90 ° therefrom. These I signal and Q signal are output from the receiving circuit 223 after the gain is adjusted.
- the control circuit 212 may control the operations of the transmission filter of the transmission circuit 222 and the reception filter of the reception circuit 223 so as to extract the signal of the channel covered by the channel according to the setting of the channel to be used. There may be another control unit that controls the transmission circuit 222 and the reception circuit 223, and the same control may be performed by the control circuit 212 issuing an instruction to the control unit.
- the AD conversion circuits 217 and 218 in the baseband unit 211 correspond to a part that performs AD conversion of each transmission / reception processing unit shown in FIG.
- the AD conversion circuits 217 and 218 perform AD conversion on the input signal from the reception circuit 223. More specifically, the AD conversion circuit 217 converts the I signal into a digital I signal, and the AD conversion circuit 218 converts the Q signal into a digital Q signal. There may be a case where only one system signal is received without performing quadrature demodulation. In this case, only one AD conversion circuit is required. In the case where a plurality of antennas are provided, the number of AD conversion circuits corresponding to the number of antennas may be provided.
- the control circuit 212 also performs processing related to MIMO, for example, propagation path estimation processing, transmission weight calculation processing, and stream separation processing.
- the reception processing circuit 214 corresponds to a part that performs reception processing of the physical layer of each of the transmission / reception processing units of the PHY processing unit and the wireless unit 70 illustrated in FIG. 3. That is, the reception processing circuit 214 performs processing such as demodulation, decoding, preamble and PHY header analysis. 3 may be included in the transmission processing circuit 213, the reception unit 82 in the reception processing circuit 214, and the access control unit 83 and the control unit 84 in the control circuit 212. It is.
- a switch for switching the antennas 1 to N to any one of the transmission circuit 222 and the reception circuit 223 may be arranged in the RF unit. By controlling the switch, the antennas 1 to N may be connected to the transmission circuit 222 during transmission, and the antennas 1 to N may be connected to the reception circuit 223 during reception.
- the DA conversion circuits 215 and 216 and the AD conversion circuits 217 and 218 are arranged on the baseband unit 211 side, but may be arranged on the RF unit 221 side.
- the transmission circuit 222 and the reception circuit 223 may form a wireless communication unit.
- the transmission circuit 222 and the reception circuit 223 may further include DA 215 and 216 and DA 217 and 218 to form a wireless communication unit.
- a wireless communication unit may be formed including the PHY processing parts of the transmission processing circuit 213 and the reception processing circuit 214.
- the wireless communication unit may be formed by the PHY reception processing parts of the transmission processing circuit 213 and the reception processing circuit 214.
- FIG. 17A and FIG. 17B are perspective views of wireless devices according to the eleventh embodiment, respectively.
- the wireless device in FIG. 17A is a notebook PC 301
- the wireless device in FIG. 17B is a mobile terminal 321.
- Each corresponds to one form of a terminal (including a base station).
- the notebook PC 301 and the mobile terminal 321 are equipped with wireless communication devices 305 and 315, respectively.
- the wireless communication devices 305 and 315 the wireless communication devices mounted on the terminals (including base stations) described so far can be used.
- a wireless device equipped with a wireless communication device is not limited to a notebook PC or a mobile terminal.
- TV digital camera, wearable device, tablet, smartphone, game device, network storage device, monitor, digital audio player, web camera, video camera, project, navigation system, external adapter, internal adapter, set top box, gateway, It can also be installed in printer servers, mobile access points, routers, enterprise / service provider access points, portable devices, handheld devices, and the like.
- the wireless communication device installed in the terminal can be installed in the memory card.
- FIG. 18 shows an example in which the wireless communication device is mounted on a memory card.
- the memory card 331 includes a wireless communication device 355 and a memory card main body 332.
- the memory card 331 uses a wireless communication device 335 for wireless communication with an external device.
- description of other elements (for example, a memory) in the memory card 331 is omitted.
- a bus, a processor unit, and an external interface unit are provided.
- the processor unit and the external interface unit are connected to an external memory (buffer) via a bus.
- Firmware operates in the processor unit.
- the processor unit on which the firmware operates may be a communication processing device according to the present embodiment, a control unit, an access control unit, or a processor that performs a plurality of these processes. Another processor may be used.
- the base station and / or wireless terminal may include a processor unit on which firmware operates.
- the processor unit may be provided in an integrated circuit in a wireless communication device mounted on a base station or an integrated circuit in a wireless communication device mounted on a wireless terminal.
- a clock generation unit In the thirteenth embodiment, in addition to the configuration of the wireless communication apparatus according to any one of the first to eleventh embodiments, a clock generation unit is provided.
- the clock generation unit generates a clock and outputs the clock from the output terminal to the outside of the wireless communication device.
- the host side and the wireless communication apparatus side can be operated in synchronization by outputting the clock generated inside the wireless communication apparatus to the outside and operating the host side with the clock output to the outside. It becomes possible.
- a power supply unit in addition to the configuration of the wireless communication apparatus according to any one of the first to eleventh embodiments, a power supply unit, a power supply control unit, and a wireless power supply unit are included.
- the power supply control unit is connected to the power supply unit and the wireless power supply unit, and performs control to select a power supply to be supplied to the wireless communication device. As described above, by providing the wireless communication apparatus with the power supply, it is possible to perform a low power consumption operation by controlling the power supply.
- the fifteenth embodiment includes a SIM card in addition to the configuration of the wireless communication apparatus according to the fourteenth embodiment.
- the SIM card is connected to, for example, a MAC processing unit or a control unit in the wireless communication device. As described above, by adopting a configuration in which the SIM card is provided in the wireless communication device, authentication processing can be easily performed.
- a moving image compression / decompression unit is included.
- the moving image compression / decompression unit is connected to the bus. As described above, by providing the wireless communication device with the moving image compression / decompression unit, it is possible to easily transmit the compressed moving image and expand the received compressed moving image.
- an LED unit is included.
- the LED unit is connected to, for example, at least one of a MAC processing unit, a transmission processing circuit, a reception processing circuit, and a control unit. As described above, by providing the wireless communication device with the LED unit, it is possible to easily notify the user of the operation state of the wireless communication device.
- the eighteenth embodiment includes a vibrator unit in addition to the configuration of the wireless communication apparatus according to any one of the first to eleventh embodiments.
- the vibrator unit is connected to, for example, at least one of a MAC processing unit, a transmission processing circuit, a reception processing circuit, and a control unit. As described above, by providing the radio communication device with the vibrator unit, it is possible to easily notify the user of the operation state of the radio communication device.
- the display may be connected to the MAC processing unit of the wireless communication device via a bus (not shown).
- a bus not shown
- [1] a frame type in a wireless communication system, [2] a method of disconnecting connections between wireless communication apparatuses, [3] an access method of a wireless LAN system, and [4] a frame interval of the wireless LAN will be described.
- [1] Frame Type in Communication System Generally, frames handled on a radio access protocol in a radio communication system are roughly classified into three types: a data frame, a management frame, and a control frame. These types are usually indicated by a header portion provided in common between frames. As a display method of the frame type, three types may be distinguished by one field, or may be distinguished by a combination of two fields.
- the management frame is a frame used for managing a physical communication link with another wireless communication device. For example, there are a frame used for setting communication with another wireless communication device, a frame for releasing a communication link (that is, disconnecting), and a frame related to a power saving operation in the wireless communication device. .
- the data frame is a frame for transmitting data generated inside the wireless communication device to the other wireless communication device after establishing a physical communication link with the other wireless communication device.
- Data is generated in an upper layer of the present embodiment, for example, generated by a user operation.
- the control frame is a frame used for control when a data frame is transmitted / received (exchanged) to / from another wireless communication apparatus.
- the wireless communication apparatus receives a data frame or a management frame, the response frame transmitted for confirmation of delivery belongs to the control frame.
- connection request frame and a connection acceptance frame are management frames, and a response frame of a control frame can be used as a confirmation frame for the connection acceptance frame.
- One of the connected wireless communication apparatuses transmits a frame for disconnection.
- This frame is classified as a management frame.
- the frame for disconnection may be called a release frame in the sense that, for example, the connection is released.
- the wireless communication device that transmits the release frame determines that the connection is disconnected when the release frame is transmitted and the wireless communication device that receives the release frame receives the release frame. Thereafter, the process returns to the initial state in the communication phase, for example, the state of searching for the wireless communication device of the communication partner. This is because when a frame for disconnection is transmitted, a physical radio link may not be secured such that a radio signal cannot be received or decoded due to a communication distance away from the connection destination radio communication device. Because.
- a frame transmission transmission of a data frame and a management frame, or transmission of a response frame to a frame transmitted by the own device
- a wireless communication device of a connection partner that has established a connection for a certain period of time. If not, it is determined whether the connection is disconnected.
- the connection is disconnected as described above, such that the communication distance is away from the connection-destination wireless communication device, and the wireless signal cannot be received or decoded. This is because a wireless link cannot be secured. That is, it cannot be expected to receive a release frame.
- a timer is used as a specific example of determining disconnection by an implicit method. For example, when transmitting a data frame requesting a delivery confirmation response frame, a first timer (for example, a retransmission timer for a data frame) that limits a retransmission period of the frame is started, and until the first timer expires (that is, If a delivery confirmation response frame is not received (until the desired retransmission period elapses), retransmission is performed. The first timer is stopped when a delivery confirmation response frame to the frame is received.
- a first timer for example, a retransmission timer for a data frame
- the first timer is stopped when a delivery confirmation response frame to the frame is received.
- the first timer expires without receiving the delivery confirmation response frame, for example, it is confirmed whether the other party's wireless communication device still exists (within the communication range) (in other words, the wireless link can be secured).
- a second timer for limiting the retransmission period of the frame (for example, a retransmission timer for the management frame) is started at the same time. Similar to the first timer, the second timer also performs retransmission if it does not receive an acknowledgment frame for the frame until the second timer expires, and determines that the connection has been disconnected when the second timer expires. .
- the third timer is started. Whenever a new frame is received from the connection partner wireless communication device, the third timer is stopped and restarted from the initial value. When the third timer expires, a management frame is transmitted to confirm whether the other party's wireless communication device still exists (within the communication range) (in other words, whether the wireless link has been secured) as described above. At the same time, a second timer (for example, a retransmission timer for management frames) that limits the retransmission period of the frame is started.
- a second timer for example, a retransmission timer for management frames
- the acknowledgment response frame to the frame is not received until the second timer expires, retransmission is performed, and if the second timer expires, it is determined that the connection has been disconnected.
- the latter management frame for confirming whether the wireless communication apparatus of the connection partner still exists may be different from the management frame in the former case.
- the timer for limiting the retransmission of the management frame is the same as that in the former case as the second timer, but a different timer may be used.
- [3] Access method of wireless LAN system For example, there is a wireless LAN system that is assumed to communicate or compete with a plurality of wireless communication devices.
- IEEE802.11 including extended standards
- wireless LAN CSMA / CA is the basic access method.
- the transmission is performed simultaneously by a plurality of wireless communication devices grasping the transmission of the wireless communication device, and as a result
- the radio signal collides and frame transmission fails.
- the transmissions by a plurality of wireless communication devices that grasp the transmission of the wireless communication device are stochastically dispersed.
- the method employing Carrier Aviation is a method suitable for sharing a wireless medium between a plurality of wireless communication devices. be able to.
- the IEEE 802.11 wireless LAN frame interval will be described.
- the frame interval used in the IEEE 802.11 wireless LAN is as follows: distributed coordination function inter frame space (DIFS), arbitration inter frame space (AIFS), point coordination function intra interface space interface (IFS).
- DIFS distributed coordination function inter frame space
- AIFS arbitration inter frame space
- IFS point coordination function intra interface space interface
- RIFS reduced interface space
- the definition of the frame interval is defined as a continuous period to be opened after confirming the carrier sense idle before transmission in the IEEE 802.11 wireless LAN, and a strict period from the previous frame is not discussed. Therefore, in the description of the IEEE802.11 wireless LAN system here, the definition follows.
- the waiting time for random access based on CSMA / CA is the sum of a fixed time and a random time, and it can be said that such a definition is used to clarify the fixed time.
- DIFS and AIFS are frame intervals used when attempting to start frame exchange during a contention period competing with other wireless communication devices based on CSMA / CA.
- the DIFS is used when priority according to the traffic type (Traffic Identifier: TID) is provided when there is no distinction of the priority according to the traffic type.
- TID Traffic Identifier
- AIFS Since the operations related to DIFS and AIFS are similar, the following description will be made mainly using AIFS.
- access control including the start of frame exchange is performed in the MAC layer.
- QoS Quality of Service
- the traffic type is notified together with the data, and the data is classified according to the priority at the time of access based on the traffic type.
- This class at the time of access is called an access category (AC). Therefore, an AIFS value is provided for each access category.
- PIFS is a frame interval for enabling access with priority over other competing wireless communication devices, and has a shorter period than either of the values of DIFS and AIFS.
- SIFS is a frame interval that can be used when transmitting a control frame of a response system or when frame exchange is continued in a burst after acquiring an access right once.
- EIFS is a frame interval that is triggered when frame reception fails.
- the RIFS is a frame interval that can be used when a plurality of frames are continuously transmitted to the same wireless communication device in bursts after acquiring the access right once. Do not request a response frame.
- FIG. 19 shows an example of frame exchange in a contention period based on random access in the IEEE 802.11 wireless LAN.
- the random time is obtained by multiplying a pseudo-random integer derived from a uniform distribution between contention windows (Content Window: CW) given by an integer from 0 to a slot time.
- CW Content Window
- CW time width CW time width.
- the initial value of CW is given by CWmin, and every time retransmission is performed, the value of CW is increased until it reaches CWmax.
- Both CWmin and CWmax have values for each access category, similar to AIFS.
- W_DATA1 When the wireless communication apparatus to which W_DATA1 is transmitted successfully receives the data frame, it transmits a response frame (W_ACK1) after SIFS from the reception end time.
- the wireless communication apparatus that has transmitted W_DATA1 can transmit the next frame (for example, W_DATA2) after SIFS if W_ACK1 is received and within the transmission burst time limit.
- AIFS, DIFS, PIFS, and EIFS are functions of SIFS and slot time, and SIFS and slot time are defined for each physical layer.
- Parameters for which values are provided for each access category, such as AIFS, CWmin, and CWmax, can be set for each communication group (Basic Service Set (BSS) in the IEEE 802.11 wireless LAN), but default values are set. .
- BSS Base Service Set
- the SIFS is 16 ⁇ s and the slot time is 9 ⁇ s.
- the PIFS is 25 ⁇ s
- the DIFS is 34 ⁇ s
- the frame interval of the access category BACKGROUND (AC_BK) in AIFS is 79 ⁇ s by default.
- the frame interval of BEST EFFORT (AC_BE) has a default value of 43 ⁇ s
- the frame interval of VIDEO (AC_VI) and VOICE (AC_VO) has a default value of 34 ⁇ s
- the default values of CWmin and CWmax are 31 and 1023 for AC_BK and AC_BE, respectively.
- AC_VI is 15 and 31
- AC_VO is 7 and 15.
- EIFS is the sum of the time lengths of response frames in the case of transmitting at the slowest required physical rate with SIFS and DIFS.
- processors may include general purpose processors, central processing units (CPUs), microprocessors, digital signal processors (DSPs), controllers, microcontrollers, state machines, and the like.
- processors may refer to an application specific integrated circuit, a field programmable gate array (FPGA), a programmable logic circuit (PLD), or the like.
- FPGA field programmable gate array
- PLD programmable logic circuit
- processor may refer to a combination of processing devices such as a plurality of microprocessors, a combination of a DSP and a microprocessor, and one or more microprocessors that cooperate with a DSP core.
- the term “memory” may encompass any electronic component capable of storing electronic information.
- “Memory” means random access memory (RAM), read only memory (ROM), programmable read only memory (PROM), erasable programmable read only memory (EPROM), electrically erasable PROM (EEPROM), non-volatile It may refer to random access memory (NVRAM), flash memory, magnetic or optical data storage, which can be read by the processor. If the processor reads and / or writes information to the memory, the memory can be said to be in electrical communication with the processor. The memory may be integrated into the processor, which again can be said to be in electrical communication with the processor.
- the present invention is not limited to the above-described embodiment as it is, and can be embodied by modifying constituent elements without departing from the scope of the invention in the implementation stage.
- various inventions can be formed by appropriately combining a plurality of components disclosed in the embodiment. For example, some components may be deleted from all the components shown in the embodiment.
- constituent elements over different embodiments may be appropriately combined.
- 101, 102, 103 Base station (AP) 201, 202, 203, 301, 401: Terminal (STA) 20, 70: PHY processing unit & radio unit 30, 80: MAC processing unit 40, 90: upper layer processing unit 31, 81: transmission unit 32, 82: reception unit 33, 83: access control unit 34, 84: control unit 111, 211: baseband units 121, 221: RF units 122, 222: transmission circuit 123, 223: reception circuit 112, 212: control circuit 113, 213: transmission processing circuits 114, 214: reception processing circuits 115, 116, 215 216: DA converter circuit 117, 118, 217, 218: AD converter circuit 301: Notebook PC 305, 315, 355: Wireless communication device 321: Mobile terminal 331: Memory card 332: Memory card body
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Abstract
Description
図1は、第1の実施形態に係る無線通信基地局と無線通信端末とを備えた無線通信システムの構成図である。この無線通信システムは、任意の通信方式に従って通信を行う。ここでは、通信方式として、IEEE802.11規格を想定するが、これに限定されるものではない。以下、無線通信基地局を基地局、無線通信端末を端末と呼ぶ。基地局も端末の一形態であり、中継機能を有する点において、非基地局の端末と異なる。
使用要求チャネル情報は、例えば、複数の連続するチャネルの割り当てを要求する場合、連続するチャネルのうち最も小さいまたは大きいチャネル番号と、割り当てを要求するチャネル数または帯域幅を特定するチャネル幅情報との少なくとも1つのセットを含む。または、連続するチャネルの最も低いチャネル番号と、最も大きいチャネル番号の少なくとも1つのセットを含む。ここでは、アソシエーション要求フレームに使用要求チャネル情報を含めたが、再アソシエーション要求フレームやその他の管理フレーム(例えば新規に定義した管理フレーム)に含めて送信することも可能である。
第1の実施形態では、端末201が、基地局101がサービスするチャネルのうち使用要求チャネルをキャリアセンスにより決定し、その情報をアソシエーション要求フレームに挿入した。本実施形態では、アソシエーション要求フレームに、使用要求チャネル情報とともに、使用要求チャネルを決定した理由を表す理由情報を含める。理由情報の形態として、本実施形態では、IEEE802.11仕様で規定された理由コード(Reason code)を用いる。理由コードは数値によって表現され、事前に定義された理由に対応づけられる。
authentication no longer valid”,“4-Way Handshake timeout”などがある。ただし、IEEE802.11仕様では、理由コードを挿入する候補フレームとして、アソシエーション要求フレームは規定されていない。そこで、本実施形態では、アソシエーション要求フレームのフレームボディフィールドに、使用要求チャネルを選択した理由の理由コードを挿入する。基地局は、端末から通知された理由コードを考慮することで、各端末により適切なチャネル割り当てを行うことが可能になる。
既にIEEE802.11として仕様が策定されている802.11acまでの規格においては、前述のように、システムとしての共通チャネル(プライマリチャネル)が一つ存在し、チャネル幅を拡張する場合にも、プライマリチャネルから順次拡張して用いるものである。この規格では、基地局が定期的に送信するビーコンフレームや、アソシエーション関連等の管理フレーム(アソシエーション要求フレーム、アソシエーション応答フレームなど)は、あくまでもプライマリチャネルにて、全て送受信される前提があった。
第1~第2の実施形態では、端末は、基地局から割り当てられたチャネルのすべてで待ち受け動作を行い、また第3の実施形態では当該チャネルに加えて、必要に応じて、システムのプライマリチャネルでも待ち受け動作を行った。
第1および第2の実施形態では、基地局101は、送信および受信を、時間的に分離して行う仕組みを想定していた。つまり、基地局101は、送信か受信のどちらか一方を、各チャネルで同時に行う場合を想定していた。チャネルごとに受信または送信タイミングが異なっていたり、送信と受信がチャネル間で混在したりする場合は想定していなかった。
第1~第5の実施形態では、各端末が決定する使用要求チャネルはそれぞれ連続したチャネルである場合を想定した。一方、例えば、チャネル1~8のうち、チャネル3~6が割り当て済みの中で、3個のチャネルを用いたいといった場合もある。この場合、連続したチャネルは最大2チャネルであるため、連続した3チャネルの割り当てはできない。そこで、離れた位置のチャネルを含めて、3チャネルを割り当てることを可能にする実施形態をここでは示す。
Information)のセット、もしくは、最小チャネル番号(Channel Number (Lower))および最大チャネル番号(Channel Number (Upper))のセットを含める。ただし、本実施形態のように、連続しない複数チャネルを要求する場合には、情報フィールドには、当該セットを複数含める。
第1~第6の実施形態ではチャネルベースのOFDMAの場合を説明したが、本実施形態ではリソースブロックベースのOFDMAの場合を説明する。ここでは、1チャネルの帯域に、互いに直交する複数のサブキャリアが含まれ、隣接する1つまたは複数のサブキャリアをリソースブロックとして、リソースブロック単位で各端末にサブキャリアを割り当てて通信する場合を想定する。但し、使用するチャネル数は1に限定されず、複数のチャネルを用いてもよい。この場合、各チャネルに複数のリソースブロックが属する。つまり、複数のリソースブロックが、複数のチャネルに属する。またチャネルごとにリソースブロックの割り当てを行うのではなく、複数のチャネルを束ねた1つの帯域内に配置される複数のサブキャリア群を対象に複数のリソースブロックを設定して、各端末にリソースブロックを割り当てることも可能である。
第1~第4の実施形態では、初期接続時のアソシエーション関連フレームのやり取りにおいて、端末にチャネルを割り当て、以降は、そのチャネルを使用し続けた。しかしながら、その後のチャネル状況の変動等から、適したチャネルが最初に決めたチャネルから変わる場合もある。そこで、チャネルの状況に応じて、接続中に、使用チャネルを変更する実施形態を示す。
(第9の実施形態)
第1~第8の実施形態で、所定周波数帯域内のチャネルは最大でチャネル1~8まであり、これらのチャネルは連続しているとしたが、このチャネルの連続について補足の説明をする。
IEEE802.11規格での5GHz帯では、基本的にチャネル番号が20MHz間隔で用いられるので、その使われているチャネル番号に則って考えて問題ない。
一方、2.4GHz帯では、図14のように、基準チャネルの選択が、北米や中国などでは25MHz間隔(図14(A))で、欧州では30MHz間隔(図14(B))で行われている。そこで、明細書中のch.1は、IEEE802.11規格での2.4GHz帯のチャネル番号1、ch.2はIEEE802.11規格での2.4GHz帯のチャネル番号6、というように、北米や中国に倣って25MHz間隔(図14(A))のものとするのでもよい。または、明細書中のch.1は、IEEE802.11規格での2.4GHz帯のチャネル番号1、ch.2はIEEE802.11規格での2.4GHz帯のチャネル番号7、というように欧州に倣って30MHz間隔((図14(B)))のものとするのでもよい。あるいは図14(C)に示すように、5GHz帯での20MHzチャネル間隔に倣い、明細書中のch.1はIEEE802.11規格での2.4GHz帯のチャネル番号1、ch.2はIEEE802.11規格での2.4GHz帯のチャネル番号5、というようにするのでもよい。図14(C)は、図14(A)および図14(B)以外に、今後考えられるチャネル選択を例示したものである。ただし、北米や中国、欧州のような場合、別の無線通信システムが、2.4GHz帯のチャネル番号6や7を、少なくとも一部のチャネルとして選択していると、チャネル番号5と一部周波数帯域が被ることになる。この場合、互いの無線通信システムが影響する周波数帯域が広がり、チャネル利用効率が下がる。
図15は、本発明の実施形態に係る端末に搭載される無線通信装置のハードウェア構成例を示したものである。このハードウェア構成は一例であり、ハードウェア構成は種々の変更が可能である。図15に示した無線通信装置の動作は、これまで図2で説明した端末の無線通信装置と同様であるため、以下では、ハードウェア構成上の違いを中心に説明し、詳細な動作の説明は省略する。
図17(A)および図17(B)は、それぞれ第11の実施形態に係る無線機器の斜視図である。図17(A)の無線機器はノートPC301であり、図17(B)の無線機器は移動体端末321である。それぞれ、端末(基地局を含む)の一形態に対応する。ノートPC301および移動体端末321は、それぞれ無線通信装置305、315を搭載している。無線通信装置305、315として、これまで説明してきた端末(基地局を含む)に搭載されていた無線通信装置を用いることができる。無線通信装置を搭載する無線機器は、ノートPCや移動体端末に限定されない。例えば、TV、デジタルカメラ、ウェアラブルデバイス、タブレット、スマートフォン、ゲーム装置、ネットワークストレージ装置、モニタ、デジタルオーディオプレーヤ、Webカメラ、ビデオカメラ、プロジェクト、ナビゲーションシステム、外部アダプタ、内部アダプタ、セットトップボックス、ゲートウェイ、プリンタサーバ、モバイルアクセスポイント、ルータ、エンタープライズ/サービスプロバイダアクセスポイント、ポータブル装置、ハンドヘルド装置等にも搭載可能である。
第12の実施形態では、第1~11のいずれかの実施形態に係る無線通信装置の構成に加えて、バス、プロセッサ部、及び外部インタフェース部を備える。プロセッサ部及び外部インタフェース部は、バスを介して外部メモリ(バッファ)と接続される。プロセッサ部ではファームウエアが動作する。このように、ファームウエアを無線通信装置に含める構成とすることにより、ファームウエアの書き換えによって無線通信装置の機能の変更を容易に行うことが可能となる。ファームウエアが動作するプロセッサ部は、本実施形態に係る通信処理装置または制御部またはアクセス制御部またはこれらの複数の処理を行うプロセッサであってもよいし、当該処理の機能拡張または変更に係る処理を行う別のプロセッサであってもよい。ファームウエアが動作するプロセッサ部を、本実施形態に係る基地局あるいは無線端末あるいはこれらの両方が備えてもよい。または当該プロセッサ部を、基地局に搭載される無線通信装置内の集積回路、または無線端末に搭載される無線通信装置内の集積回路が備えてもよい。
第13の実施形態では、第1~11のいずれかの実施形態に係る無線通信装置の構成に加えて、クロック生成部を備える。クロック生成部は、クロックを生成して出力端子より無線通信装置の外部にクロックを出力する。このように、無線通信装置内部で生成されたクロックを外部に出力し、外部に出力されたクロックによってホスト側を動作させることにより、ホスト側と無線通信装置側とを同期させて動作させることが可能となる。
第14の実施形態では、第1~11のいずれかの実施形態に係る無線通信装置の構成に加えて、電源部、電源制御部、及び無線電力給電部を含む。電源制御部は、電源部と無線電力給電部とに接続され、無線通信装置に供給する電源を選択する制御を行う。このように、電源を無線通信装置に備える構成とすることにより、電源を制御した低消費電力化動作が可能となる。
第15の実施形態では、第14の実施形態に係る無線通信装置の構成に加えて、SIMカードを含む。SIMカードは、例えば、無線通信装置におけるMAC処理部または制御部と接続される。このように、SIMカードを無線通信装置に備える構成とすることにより、容易に認証処理を行うことが可能となる。
第16の実施形態では、第12の実施形態に係る無線通信装置の構成に加えて、動画像圧縮/伸長部を含む。動画像圧縮/伸長部は、バスと接続される。このように、動画像圧縮/伸長部を無線通信装置に備える構成とすることにより、圧縮した動画像の伝送と受信した圧縮動画像の伸長とを容易に行うことが可能となる。
第17の実施形態では、第1~11のいずれかの実施形態に係る無線通信装置の構成に加えて、LED部を含む。LED部は、例えば、MAC処理部、送信処理回路、受信処理回路、制御部の少なくとも1つと接続される。このように、LED部を無線通信装置に備える構成とすることにより、無線通信装置の動作状態を、ユーザに容易に通知することが可能となる。
第18の実施形態では、第1~11のいずれかの実施形態に係る無線通信装置の構成に加えて、バイブレータ部を含む。バイブレータ部は、例えば、MAC処理部、送信処理回路、受信処理回路、制御部の少なくとも1つと接続される。このように、バイブレータ部を無線通信装置に備える構成とすることにより、無線通信装置の動作状態を、ユーザに容易に通知することが可能となる。
第19の実施形態では、第1~第11のいずれかの実施形態に係る無線通信装置(基地局の無線通信装置または無線端末の無線通信装置、またはこれらの両方)の構成に加えて、ディスプレイを含む。ディスプレイは、図示しないバスを介して、無線通信装置のMAC処理部に接続されてもよい。このようにディスプレイを備える構成とし、無線通信装置の動作状態をディスプレイに表示することで、無線通信装置の動作状態をユーザに容易に通知することが可能となる。
本実施形態では、[1]無線通信システムにおけるフレーム種別、[2]無線通信装置間の接続切断の手法、[3]無線LANシステムのアクセス方式、[4]無線LANのフレーム間隔について説明する。
[1]通信システムにおけるフレーム種別
一般的に無線通信システムにおける無線アクセスプロトコル上で扱うフレームは、大別してデータフレーム、管理フレーム、制御フレームの3種類に分けられる。これらの種別は、通常、フレーム間で共通に設けられるヘッダ部で示される。フレーム種別の表示方法としては、1つのフィールドで3種類を区別できるようにしてあってもよいし、2つのフィールドの組み合わせで区別できるようにしてあってもよい。
接続の切断には、明示的な手法と暗示的な手法とがある。明示的な手法としては、接続している無線通信装置のいずれか一方が切断のためのフレームを送信する。このフレームは管理フレームに分類される。切断のためのフレームは、例えば接続をリリースするという意味でリリースフレームと呼ぶことがある。通常、リリースフレームを送信する側の無線通信装置ではリリースフレームを送信した時点で、リリースフレームを受信する側の無線通信装置ではリリースフレームを受信した時点で、接続の切断と判定する。その後、通信フェーズでの初期状態、例えば通信相手の無線通信装置を探索する状態に戻る。これは、切断のためのフレームを送信する際には、接続先の無線通信装置と通信距離が離れて無線信号が受信不可あるいは復号不可になるといった、物理的な無線リンクが確保できないことがあるからである。
例えば、複数の無線通信装置と通信または競合することを想定した無線LANシステムがある。IEEE802.11(拡張規格なども含む)無線LANではCSMA/CAをアクセス方式の基本としている。ある無線通信装置の送信を把握し、その送信終了から固定時間を置いて送信を行う方式では、その無線通信装置の送信を把握した複数の無線通信装置で同時に送信を行うことになり、その結果、無線信号が衝突してフレーム送信に失敗する。ある無線通信装置の送信を把握し、その送信終了からランダム時間待つことで、その無線通信装置の送信を把握した複数の無線通信装置での送信が確率的に分散することになる。よって、ランダム時間の中で最も早い時間を引いた無線通信装置が1つなら無線通信装置のフレーム送信は成功し、フレームの衝突を防ぐことができる。ランダム値に基づき送信権の獲得が複数の無線通信装置間で公平になることから、Carrier Avoidanceを採用した方式は、複数の無線通信装置間で無線媒体を共有するために適した方式であるということができる。
IEEE802.11無線LANのフレーム間隔について説明する。IEEE802.11無線LANで用いられるフレーム間隔は、distributed coordination function interframe space(DIFS)、arbitration interframe space(AIFS)、point coordination function interframe space(PIFS)、short interframe space(SIFS)、extended interframe space(EIFS)、reduced interframe space(RIFS)の6種類ある。
201、202、203、301、401:端末(STA)
20、70:PHY処理部&無線部
30、80:MAC処理部
40、90:上位層処理部
31、81:送信部
32、82:受信部
33、83:アクセス制御部
34、84:制御部
111、211:ベースバンド部
121、221:RF部
122、222:送信回路
123、223:受信回路
112、212:制御回路
113、213:送信処理回路
114、214:受信処理回路
115、116、215、216:DA変換回路
117、118、217、218:AD変換回路
301:ノートPC
305、315、355:無線通信装置
321:移動体端末
331:メモリーカード
332:メモリーカード本体
Claims (27)
- 複数のリソースブロックのうち、割り当てを要求する1つまたは複数のリソースブロックを指定した第1の情報を送信する送信手段と、
前記第1情報に応じて割り当てられた1つまたは複数のリソースブロックを指定した第2情報を受信する受信手段と、
前記第2情報で指定されたリソースブロックで、信号を送受信するよう制御する制御手段と、
を備えた無線通信端末。 - 前記複数のリソースブロックは、1つまたは複数のチャネルに属し、
前記複数のチャネルのキャリアセンスに基づき、前記1つまたは複数のチャネルに属するリソースブロックを選択する選択手段を備え、
前記送信手段は、前記選択手段により選択されたチャネルと前記選択されたチャネルに属する少なくとも1つのリソースブロックとを指定した前記第1情報を送信する
請求項1に記載の無線通信端末。 - 前記選択手段は、1つまたは複数の連続するリソースブロックを選択する
請求項は2に記載の無線通信端末。 - 前記第1情報は、
前記連続するリソースブロックのうち最も小さいまたは大きいリソースブロック番号と、割り当てを要求するリソースブロック数または帯域幅を特定するリソースブロック幅情報との少なくとも1つのセット、もしくは、
前記連続するリソースブロックの最も低いリソースブロック番号と最も大きいリソースブロック番号の少なくとも1つのセット
を含む請求項1ないし3のいずれか一項に記載の無線通信端末。 - 前記送信手段は、前記第1情報で指定されたリソースブロックを指定した理由を表す理由情報をさらに送信する
請求項1ないし4のいずれか一項に記載の無線通信端末。 - 前記制御手段は、前記第2情報で指定されたリソースブロックで、フレームの待ち受け動作を行うよう制御する
請求項1ないし5のいずれか一項に記載の無線通信端末。 - 前記複数のリソースブロックは、1つまたは複数のチャネルに属し、
前記制御手段は、前記第2情報で指定されたリソースブロックが、予め定めたチャネルに属していない場合は、前記予め定めたチャネルでも前記待ち受け動作を行うよう制御する
請求項6に記載の無線通信端末。 - 前記制御手段は、前記第2情報で指定されたリソースブロックの一部のリソースブロックで、フレームの待ち受けと信号受信を行うよう制御し、前記第2情報で指定されたリソースブロックのうち前記一部のリソースブロック以外のリソースブロックではキャリアセンスを行うよう制御し、
前記一部のリソースブロックで自装置宛の送信許可を要求する第1フレームを受信した場合は、前記第2情報で指定されたリソースブロックのうちアイドルのリソースブロックと、前記制御フレームを受信したリソースブロックとで、送信許可を通知する第2フレームを送信し、前記第2フレームを送信したリソースブロックで、第3フレームの待ち受け動作を行うよう制御する
請求項1ないし5のいずれか一項に記載の無線通信端末。 - 前記送信手段は、接続を要求する第4フレームを送信し、前記第4フレームは第1情報を含む
請求項1ないし8のいずれか一項に記載の無線通信端末。 - 前記第4フレームは、IEEE802.11の管理フレームであり、前記第1情報は、前記管理フレームの情報エレメントフィールドに格納される
請求項9に記載の無線通信端末。 - 前記制御手段は、他の無線通信端末が複数のチャネルでの送信および受信をそれぞれ独立したタイミングで行う通信方式へ対応する能力を有するかを前記他の無線通信端末から送信される第3情報に基づき判断し、前記他の無線通信端末が前記能力を有さない場合は、少なくとも予め定めた第1チャネルを含む1つ以上のチャネルで、前記第4フレームを送信するよう制御する
請求項9または10に記載の無線通信端末。 - 前記制御手段は、他の無線通信端末が複数のチャネルでの送信および受信をそれぞれ独立したタイミングで行う通信方式へ対応する能力を有するかを前記他の無線通信端末から送信される第3情報に基づき判断し、前記他の無線通信端末が前記対応能力を有する場合は、前記第1情報で指定するリソースブロックが属するチャネルの一部または全部で、前記第4フレームを送信するよう制御する
請求項9ないし11のいずれか一項に記載の無線通信端末。 - IEEE802.11規格に従って通信する
請求項1ないし12のいずれか一項に記載の無線通信端末。 - 請求項1ないし13のいずれか一項に記載の前記送信手段と、前記受信手段と、前記制御手段とを含む通信処理装置と、
少なくとも1つのアンテナと
前記アンテナを介して信号を送受信する無線通信部と
を備えた無線通信端末。 - 請求項1ないし13のいずれか一項に記載の送信手段と、受信手段と、制御手段とを含む通信処理装置と、
少なくとも1つのアンテナと
前記アンテナを介して信号を送受信する無線通信部と
を備えたメモリーカード。 - 複数のリソースブロックのうち、割り当てを要求する1つまたは複数のリソースブロックを指定した第1情報を、複数の他の無線通信端末からそれぞれ受信する受信手段と、
前記第1情報に基づいて前記複数の他の無線通信端末に1つまたは複数のリソースブロックを割り当てる制御手段と、
前記制御手段により割り当てられたリソースブロックを指定した第2情報を、前記複数の他の無線通信端末に送信する送信手段と、を備え、
前記制御手段は、前記第2情報で指定されたリソースブロックを用いて、前記複数の他の無線通信端末と信号を送受信するよう制御する
無線通信端末。 - 前記制御手段は、前記通信装置に1つまたは複数の連続するリソースブロックを割り当てる
請求項16に記載の無線通信端末。 - 前記第2情報は、
前記連続するリソースブロックのうち最も小さいまたは大きいリソースブロック番号と、割り当てを要求するリソースブロック数または帯域幅を特定するリソースブロック幅情報との少なくとも1つのセット、もしくは、
前記連続するリソースブロックの最も低いリソースブロック番号と最も大きいリソースブロック番号の少なくとも1つのセット
請求項17に記載の無線通信端末。 - 前記第1情報は、前記第1情報で指定されるリソースブロックを指定した理由を表す理由情報を含み、
前記制御手段は、前記理由情報に基づき前記リソースブロックの割り当てを行う
請求項16ないし18のいずれか一項に記載の無線通信端末。 - 前記送信手段は、接続を要求する第1フレームを受信し、前記第2情報を含む第2フレームを応答として送信する
請求項16ないし19のいずれか一項に記載の無線通信端末。 - 前記第2フレームは、IEEE802.11の管理フレームであり、前記第2リソースブロック情報は、前記管理フレームの情報エレメントフィールドに格納される
請求項20に記載の無線通信端末。 - 前記送信手段は、ブロードキャストでフレームを送信する際は、前記通信装置にそれぞれ割り当てたリソースブロックの少なくとも一部にて前記フレームを同時に送信する
請求項16ないし21のいずれか一項に記載の無線通信端末。 - 前記複数のリソースブロックは、複数のチャネルに属し、
前記送信手段は、前記複数のチャネルでの送信および受信をそれぞれ独立したタイミングで行う通信方式へ対応する能力を有することを表す第3情報を送信し、
前記受信手段は、前記複数のチャネルにてそれぞれ独立したタイミングで前記他の無線通信端末から前記第1チャネル情報の受信を受け付ける
請求項16ないし22のいずれか一項に記載の無線通信端末。 - IEEE802.11規格に従って通信する
請求項16ないし23のいずれか一項に記載の無線通信端末。 - 複数のリソースブロックのうち、割り当てを要求する1つまたは複数のリソースブロックを指定した第1の情報を送信する送信ステップと、
前記第1情報に応じて割り当てられる1つまたは複数のリソースブロックを指定した第2情報を受信する受信ステップと、
前記第2情報で指定されたリソースブロックで、信号を送受信するよう制御する制御ステップと、
を備えた無線通信方法。 - 複数のリソースブロックのうち、割り当てを要求する1つまたは複数のリソースブロックを指定した第1情報を、複数の他の無線通信端末からそれぞれ受信する受信ステップと、
前記第1情報に基づき、前記複数の他の無線通信端末に、1つまたは複数のリソースブロックを割り当てる割り当てステップと、
前記割り当てステップにより割り当てられたリソースブロックを指定した第2情報を、前記複数の他の無線通信端末に送信する送信ステップと、
前記割り当てたチャネルを用いて、前記複数の他の無線通信端末と信号を送受信するよう制御する制御ステップと
を備えた無線通信方法。 - 複数の第1無線通信端末と、第2無線通信端末とが実行する無線通信方法であって、
複数のリソースブロックのうち、割り当てを要求する1つまたは複数のリソースブロックを指定した第1の情報を前記複数の第1無線通信端末のそれぞれから前記第2無線通信端末に送信し、
前記第2無線通信端末により、前記第1情報に基づき、前記第1無線通信端末のそれぞれに1つまたは複数のリソースブロックを割り当て、割り当てたリソースブロックを指定した第2情報を前記複数の第1無線通信端末のそれぞれに送信し、
前記複数の第1無線通信端末のそれぞれと前記第2無線通信端末との間で、前記第2情報で指定されたチャネルで信号を送受信する
無線通信方法。
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JP2017228937A (ja) * | 2016-06-22 | 2017-12-28 | 日本電信電話株式会社 | Fdma通信システム、fdma通信方法、基地局装置および端末局装置 |
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US10568089B2 (en) | 2020-02-18 |
US20210227541A1 (en) | 2021-07-22 |
US11653339B2 (en) | 2023-05-16 |
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EP3136804A1 (en) | 2017-03-01 |
EP3934353A1 (en) | 2022-01-05 |
JPWO2015163335A1 (ja) | 2017-04-20 |
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JP2018201254A (ja) | 2018-12-20 |
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