WO2021246203A1 - Wireless communication device - Google Patents

Abstract

This wireless communication device comprises: a reception unit that receives control information relating to a plurality of connections (multilink); and a frame transmission unit that transmits frames associated with the plurality of connections. The plurality of connections is constituted by two or more connections. The control information includes information relating to a transmission opportunity. The frame transmission unit is capable of transmitting frames to the transmission opportunity based on the information relating to the transmission opportunity.

Description

Wireless communication device

The present invention relates to a communication device and a communication method.
The present application claims priority with respect to Japanese Patent Application No. 2020-96548 filed in Japan on June 3, 2020, the contents of which are incorporated herein by reference.

IEEE802.11ax, which realizes further speedup of IEEE802.11, which is a wireless LAN (Local Area Network) standard, is being specified by IEEE (The Institute of Electrical and Electronics Engineers Inc.) and conforms to the specification draft. Wireless LAN devices have appeared on the market. Currently, standardization activities for IEEE802.11be have been started as a successor standard to IEEE802.11ax. With the rapid spread of wireless LAN devices, in the standardization of IEEE802.11be, further improvement of throughput per user is being studied in an overcrowded environment of wireless LAN devices.

In wireless LAN, frame transmission can be performed using an unlicensed band that can carry out wireless communication without the need for permission (license) from the country / region. Currently widely used unlicensed band includes 2.4 GHz band and 5 GHz band. While the coverage of the 2.4 GHz band can be relatively wide, the influence of interference between communication devices is large, and the communication bandwidth cannot be wide. On the other hand, while the 5 GHz band can have a wide communication band, it cannot have a wide coverage. Therefore, in order to realize various service applications on a wireless LAN, it is necessary to appropriately switch the frequency band to be used. However, in the conventional wireless LAN device, it is necessary to disconnect the current connection once in order to switch the frequency band used for communication.

Therefore, in the standardization of IEEE802.11be, there is a discussion about a multi-link operation (MLO) that enables a communication device to maintain a plurality of connections (links) (Non-Patent Document 1). reference). According to the MLO, the communication device can maintain a plurality of connections having different settings related to the wireless resources used and communication. That is, by using the MLO, the communication device can maintain the connection of different frequency bands at the same time, so that the frequency band for transmitting the frame can be changed without performing the reconnection operation.

However, using MLO means that frames may be transmitted and received independently in a plurality of connections. This means that when frame transmission is performed on one connection, frame reception may be performed on another connection at the same time. In order to perform MLO, frame transmission is performed. It means that the communication device must support simultaneous transmission / reception (Simultaneously Transmission and Reception: STR) that simultaneously receives and receives frames. However, it is difficult for all communication devices to support the implementation of STR because of the high hardware requirements.

One aspect of the present invention has been made in view of the above problems, and an object thereof is an access point device or station that efficiently implements MLO in a wireless LAN system in which STR compatible devices and non-STR compatible devices coexist. It discloses a device and a communication method.

The wireless communication device according to one aspect of the present invention for solving the above-mentioned problems is as follows.

(1) That is, the wireless communication device according to one aspect of the present invention transmits a receiving unit that receives control information related to a plurality of connections (multi-link, Multi-Link) and a frame associated with the plurality of connections. The plurality of connections include a frame transmission unit, and the plurality of connections are composed of two or more connections, the control information includes information related to the transmission opportunity, and the frame transmission unit is a transmission opportunity based on the information related to the transmission opportunity. Send a frame to.

(2) Further, the wireless communication device according to one aspect of the present invention is described in (1) above, and the response frame is received in all the connections constituting the plurality of connections, and the response frame is received upon completion. Send a response request frame so that the transmission opportunity ends.

(3) Further, the wireless communication device according to one aspect of the present invention is described in (1) above, and the transmission opportunity is briefly updated before the transmission opportunity ends.

(4) Further, the wireless communication device according to one aspect of the present invention is described in (1) above, and at least one of the plurality of connections is configured and the transmission opportunity is abandoned before the end of the transmission opportunity. The connection causes another connection that maintains the transmission opportunity to transmit the response request frame.

(5) Further, the wireless communication device according to one aspect of the present invention is described in the above (1), and the transmission opportunity is effective only in a part of the connections constituting the plurality of connections.

(6) Further, the wireless communication device according to one aspect of the present invention is described in the above (1), and the control information related to the plurality of connections (multilink) is used as a control frame for establishing the plurality of connections. included.

(7) Further, the wireless communication device according to one aspect of the present invention is described in the above (1), and the control information related to the plurality of connections (multilink) is included in the notification frame transmitted by the access point device. ..

According to one aspect of the present invention, in a wireless LAN system in which STR compatible devices and non-STR compatible devices coexist, MLO can be efficiently performed, which can contribute to improvement of user throughput of the wireless LAN device. can.

It is a figure which shows an example of the frame structure which concerns on one aspect of this invention. It is a figure which shows an example of the frame structure which concerns on one aspect of this invention. It is a figure which shows an example of the communication which concerns on one aspect of this invention. It is a schematic diagram which shows the division example of the radio medium which concerns on one aspect of this invention. It is a figure which shows one configuration example of the communication system which concerns on one aspect of this invention. It is a block diagram which shows one configuration example of the wireless communication apparatus which concerns on one aspect of this invention. It is a block diagram which shows one configuration example of the wireless communication apparatus which concerns on one aspect of this invention. It is a schematic diagram which shows an example of the coding method which concerns on one aspect of this invention. It is a schematic diagram which shows an example of the coding method which concerns on one aspect of this invention. It is a schematic diagram of the communication sequence which concerns on one aspect of this invention. It is a schematic diagram of the communication which concerns on one aspect of this invention. It is a schematic diagram of the communication which concerns on one aspect of this invention. It is a schematic diagram of the communication which concerns on one aspect of this invention. It is a schematic diagram of the communication which concerns on one aspect of this invention. It is an example of a table related to the operation mode of communication according to one aspect of the present invention. It is an example of a table related to the operation mode of communication according to one aspect of the present invention.

The communication system in the present embodiment includes a wireless transmission device (access point device, base station device: Accesspoint, base station device), and a plurality of wireless reception devices (station device, terminal device: station, terminal device). Further, a network composed of a base station device and a terminal device is called a basic service set (BSS: Basic service set, management range). Further, the station device according to the present embodiment can be provided with the function of the access point device. Similarly, the access point device according to the present embodiment can be provided with the function of a station device. Therefore, in the following, when simply referred to as a communication device, the communication device can refer to both a station device and an access point device.

The base station device and the terminal device in the BSS shall communicate with each other based on CSMA / CA (Carrier sense multiple access with collision avoidance). In the present embodiment, the infrastructure mode in which the base station device communicates with a plurality of terminal devices is targeted, but the method of the present embodiment can also be implemented in the ad hoc mode in which the terminal devices directly communicate with each other. In ad hoc mode, the terminal device replaces the base station device and forms a BSS. BSS in ad hoc mode is also referred to as IBSS (Independent Basic Service Set). In the following, the terminal device forming the IBSS in the ad hoc mode can also be regarded as a base station device. The method of the present embodiment can also be carried out by WiFi Direct (registered trademark) in which terminal devices directly communicate with each other. WiFi
In Direct, the terminal device replaces the base station device and forms a group. In the following, the terminal device of the group owner forming a group in WiFi Direct can also be regarded as a base station device.

In the 802.11 system, each device can transmit transmission frames of a plurality of frame types having a common frame format. The transmission frame is defined by a physical (PHY) layer, a medium access control (MAC) layer, and a logical link control (LLC: Logical Link Control) layer, respectively.

The transmission frame of the PHY layer is called a physical protocol data unit (PPDU: PHY protocol data unit, physical layer frame). The PPDU includes a physical layer header (PHY header) containing header information for performing signal processing in the physical layer, and a physical service data unit (PSDU: PHY service data unit, which is a data unit processed in the physical layer. MAC layer frame) etc. The PSDU can be composed of an aggregated MPDU (A-MPDU: Aggregated MPDU) in which a plurality of MAC protocol data units (MPDUs: MAC protocol data units), which are retransmission units in the radio section, are aggregated.

In the PHY header, a short training field (STF: Short training field) used for signal detection / synchronization, a long training field (LTF: Long training field) used to acquire channel information for data demodulation, etc. A reference signal and a control signal such as a signal (Signal: SIG) containing control information for data demodulation are included. In addition, STFs are Legacy STF (L-STF: Legacy-STF), High Throughput STF (HT-STF: Highthroughput-STF), and Ultra High Throughput STF (VHT-STF: Very), depending on the corresponding standard. It is classified into high-throughput-STF), high-efficiency STF (HE-STF: High-efficiency-STF), ultra-high-throughput STF (EHT-STF: Extremely High Throughput-STF), etc., and LTF and SIG are also L-. It is classified into LTF, HT-LTF, VHT-LTF, HE-LTF, L-SIG, HT-SIG, VHT-SIG, HE-SIG, and EHT-SIG. VHT-SIG is further classified into VHT-SIG-A1, VHT-SIG-A2 and VHT-SIG-B. Similarly, HE-SIG is classified into HE-SIG-A1-4 and HE-SIG-B. In addition, the Universal SIGNAL (U-SIG) field, which contains additional control information, can be included, assuming a technical update in the same standard.

Further, the PHY header can include information for identifying the BSS of the transmission source of the transmission frame (hereinafter, also referred to as BSS identification information). The information that identifies the BSS can be, for example, the SSID (Service Set Identifier) of the BSS or the MAC address of the base station device of the BSS. Further, the information for identifying the BSS can be a value unique to the BSS (for example, BSS Color or the like) other than the SSID and the MAC address.

PPDU is modulated according to the corresponding standard. For example, in the case of the IEEE802.11n standard, it is modulated into an orthogonal frequency division multiplexing (OFDM) signal.

The MPDU is a MAC layer header (MAC header) that includes header information for signal processing in the MAC layer, and a MAC service data unit (MSDU: MAC service data unit) that is a data unit processed in the MAC layer. It consists of a frame body and a frame inspection unit (Frame check sequence: FCS) that checks whether there are any errors in the frame. Further, a plurality of MSDUs can be aggregated as an aggregated MSDU (A-MSDU: Aggregated MSDU).

The frame types of transmission frames in the MAC layer are roughly classified into three types: management frames that manage the connection status between devices, control frames that manage the communication status between devices, and data frames that include actual transmission data. Each is further classified into a plurality of subframe types. The control frame includes a reception completion notification (Ack: Acknowledge) frame, a transmission request (RTS: Request to send) frame, a reception preparation completion (CTS: Clear to send) frame, and the like. The management frame includes a beacon frame, a probe request frame, a probe response frame, an authentication frame, an association request frame, an association response frame, and the like. included. The data frame includes a data frame, a polling (CF-poll) frame, and the like. Each device can grasp the frame type and subframe type of the received frame by reading the contents of the frame control field included in the MAC header.

Note that Ac may include Block Ac. Block Ac can perform reception completion notification to a plurality of MPDUs.

The beacon frame includes a period (Beacon interval) in which the beacon is transmitted and a field (Field) in which the SSID is described. The base station device can periodically notify the beacon frame in the BSS, and the terminal device can grasp the base station device around the terminal device by receiving the beacon frame. The fact that the terminal device grasps the base station device based on the beacon frame notified from the base station device is called passive scanning. On the other hand, searching for a base station device by notifying the probe request frame in the BSS by the terminal device is called active scanning. The base station apparatus can transmit a probe response frame as a response to the probe request frame, and the description content of the probe response frame is equivalent to that of the beacon frame.

After recognizing the base station device, the terminal device performs connection processing to the base station device. The connection process is classified into an authentication procedure and an association procedure. The terminal device sends an authentication frame (authentication request) to the base station device that wishes to connect. When the base station device receives the authentication frame, it transmits an authentication frame (authentication response) including a status code indicating whether or not the terminal device can be authenticated to the terminal device. By reading the status code written in the authentication frame, the terminal device can determine whether or not the own device has been authorized by the base station device. The base station device and the terminal device can exchange authentication frames a plurality of times.

Following the authentication procedure, the terminal device sends a connection request frame to perform the connection procedure to the base station device. When the base station device receives the connection request frame, it determines whether or not to allow the connection of the terminal device, and transmits a connection response frame to notify the fact. In the connection response frame, in addition to the status code indicating whether or not the connection processing is possible, the association identification number (AID: Association identifier) for identifying the terminal device is described. The base station device can manage a plurality of terminal devices by setting different AIDs for the terminal devices for which connection permission has been issued.

After the connection process is performed, the base station device and the terminal device perform the actual data transmission. In the 802.11 system, a distributed control mechanism (DCF: Distributed Coordination Function) and a centralized control mechanism (PCF: Point Coordination Function), and an extended mechanism (EDCA: Enhanced distributed channel access), and A hybrid control mechanism (HCF: Hybrid coordination function), etc.) is defined. In the following, a case where the base station apparatus transmits a signal to the terminal apparatus by DCF will be described as an example.

In DCF, the base station device and the terminal device perform carrier sense (CS: Carrier sense) to confirm the usage status of the wireless channel around the own device prior to communication. For example, when a base station apparatus that is a transmitting station receives a signal on the radio channel higher than a predetermined clear channel evaluation level (CCA level: Clear channel assessment level), the transmission of a transmission frame on the radio channel is transmitted. put off. Hereinafter, in the radio channel, a state in which a signal of CCA level or higher is detected is referred to as a busy state, and a state in which a signal of CCA level or higher is not detected is referred to as an idle state. Such CS performed based on the power (received power level) of the signal actually received by each device is called physical carrier sense (physical CS). The CCA level is also called a carrier sense level (CS level) or a CCA threshold (CCA threshold: CCAT). When the base station device and the terminal device detect a signal of the CCA level or higher, the base station device and the terminal device start an operation of demodulating at least the signal of the PHY layer.

The base station device performs carrier sense for the transmission frame to be transmitted only at the frame interval (IFS: Interframe space) according to the type, and determines whether the wireless channel is in the busy state or the idle state. The carrier sense period of the base station apparatus depends on the frame type and subframe type of the transmission frame to be transmitted by the base station apparatus from now on. In the 802.11 system, multiple IFSs with different periods are defined, and the short frame interval (SIFS: Short IFS) used for the transmission frame given the highest priority, and the transmission frame with a relatively high priority. There are polling frame intervals (PCFIFS: 802.11) used, distributed control frame intervals (DCFIFS: 802.11) used for transmission frames with the lowest priority, and the like. When the base station apparatus transmits a data frame by DCF, the base station apparatus uses DIFS.

The base station device waits only for DIFS, and then waits for a random backoff time to prevent frame collision. In the 802.11 system, a random backoff time called a contention window (CW) is used. CSMA / CA presupposes that a transmission frame transmitted by a certain transmitting station is received by the receiving station without interference from another transmitting station. Therefore, if the transmitting stations transmit transmission frames at the same timing, the frames collide with each other, and the receiving station cannot receive correctly. Therefore, the frame collision is avoided by each transmitting station waiting for a randomly set time before the transmission starts. When the base station apparatus determines that the radio channel is in the idle state by the carrier sense, the CW countdown is started, the transmission right is acquired only when the CW becomes 0, and the transmission frame can be transmitted to the terminal apparatus. If the base station apparatus determines that the radio channel is in a busy state by carrier sense during the CW countdown, the CW countdown is stopped. Then, when the radio channel becomes idle, the base station apparatus restarts the countdown of the remaining CW following the previous IFS.

The terminal device, which is the receiving station, receives the transmission frame, reads the PHY header of the transmission frame, and demodulates the received transmission frame. Then, the terminal device can recognize whether or not the transmission frame is addressed to the own device by reading the MAC header of the demodulated signal. The terminal device may determine the destination of the transmission frame based on the information described in the PHY header (for example, the group identifier (GID: Group identifier, Group ID) described in VHT-SIG-A). It is possible.

The terminal device determines that the received transmission frame is addressed to its own device, and if the transmission frame can be demodulated without error, the terminal device transmits an ACK frame indicating that the frame was correctly received to the base station device which is the transmission station. Must. The ACK frame is one of the highest priority transmission frames transmitted only by waiting for the SIFS period (no random backoff time is taken). The base station apparatus ends a series of communications upon receiving the ACK frame transmitted from the terminal apparatus. If the terminal device cannot receive the frame correctly, the terminal device does not transmit ACK. Therefore, if the base station apparatus does not receive the ACK frame from the receiving station for a certain period (SIFS + ACK frame length) after the frame transmission, the communication is considered to have failed and the communication is terminated. In this way, the termination of one communication (also called burst) of the IEEE 802.11 system is a special case such as the transmission of a broadcast signal such as a beacon frame or the case where fragmentation for dividing the transmission data is used. Except for this, it is always judged by whether or not the ACK frame is received.

When the terminal device determines that the received transmission frame is not addressed to its own device, the terminal device determines that the transmission frame is not addressed to the own device, and based on the length of the transmission frame described in the PHY header or the like, the terminal device (NAV: Network allocation) vector) is set. The terminal device does not attempt communication for the period set in NAV. That is, since the terminal device performs the same operation as when the wireless channel is determined to be busy by the physical CS for a period set in NAV, the communication control by NAV is also called virtual carrier sense (virtual CS). NAV is set based on the information described in the PHY header, as well as the transmission request (RTS: Request to send) frame introduced to solve the hidden terminal problem and the reception ready (CTS: Clear). to send) It is also set by the frame.

In contrast to DCF, where each device performs carrier sense and autonomously acquires transmission rights, a control station called a point coordinator (PC) controls the transmission rights of each device in the BSS. Generally, the base station device becomes a PC, and the transmission right of the terminal device in the BSS is acquired.

The communication period by PCF includes a non-competitive period (CFP: Contention free period) and a competitive period (CP: Contention period). During the CP, communication is performed based on the DCF described above, and the PC controls the transmission right during the CFP. The base station device, which is a PC, notifies the beacon frame in which the CFP period (CFP Max duration) and the like are described in the BSS prior to the PCF communication. Note that PIFS is used to transmit the beacon frame notified at the start of PCF transmission, and the beacon frame is transmitted without waiting for CW. The terminal device that has received the beacon frame sets the period of CFP described in the beacon frame to NAV. After that, until the NAV elapses or a signal for notifying the end of CFP (for example, a data frame including CF-end) is received in the BSS, the terminal device signals the acquisition of the transmission right transmitted from the PC. The transmission right can be acquired only when a signal (for example, a data frame including CF-poll) is received. Since no packet collision occurs within the same BSS within the CFP period, each terminal device does not take the random backoff time used in the DCF.

The wireless medium can be divided into a plurality of resource units (Resource units: RU). FIG. 4 is a schematic diagram showing an example of a divided state of the wireless medium. For example, in resource division example 1, the wireless communication device can divide the frequency resource (subcarrier), which is a wireless medium, into nine RUs. Similarly, in resource division example 2, the wireless communication device can divide the subcarrier, which is a wireless medium, into five RUs. As a matter of course, the resource division example shown in FIG. 4 is only one example, and for example, a plurality of RUs can be configured by different numbers of subcarriers. Further, the radio medium divided as the RU can include not only frequency resources but also spatial resources. The wireless communication device (for example, AP) can transmit a frame to a plurality of terminal devices (for example, a plurality of STAs) at the same time by arranging frames addressed to different terminal devices in each RU. The AP can describe information (Resource allocation information) indicating the division state of the wireless medium as common control information in the PHY header of the frame transmitted by the own device. Further, the AP can describe the information (resource unit assignment information) indicating the RU in which the frame addressed to each STA is arranged in the PHY header of the frame transmitted by the own device as the unique control information.

Further, a plurality of terminal devices (for example, a plurality of STAs) can transmit frames at the same time by arranging frames in their assigned RUs and transmitting them. The plurality of STAs can perform frame transmission after waiting for a predetermined period after receiving a frame (Trigger frame: TF) including trigger information transmitted from the AP. Each STA can grasp the RU assigned to its own device based on the information described in the TF. In addition, each STA can acquire RU by random access based on the TF.

AP can assign multiple RUs to one STA at the same time. The plurality of RUs may be composed of continuous subcarriers or discontinuous subcarriers. The AP can transmit one frame by using a plurality of RUs assigned to one STA, and can transmit a plurality of frames by assigning them to different RUs. At least one of the plurality of frames can be a frame containing common control information for a plurality of terminal devices for transmitting Resource allocation information.

One STA can be assigned multiple RUs from the AP. The STA can transmit one frame using a plurality of assigned RUs. Further, the STA can allocate a plurality of frames to different RUs and transmit the plurality of frames by using the plurality of assigned RUs. The plurality of frames can be frames of different frame types.

AP can assign multiple AIDs to one STA. The AP can assign RU to each of a plurality of AIDs assigned to one STA. The AP can transmit different frames to a plurality of AIDs assigned to one STA by using the assigned RUs. The different frames can be frames of different frame types.

One STA can be assigned multiple AIDs from the AP. One STA can be assigned a RU for each of a plurality of assigned AIDs. One STA recognizes that the RUs assigned to the plurality of AIDs assigned to the own device are all the RUs assigned to the own device, and transmits one frame using the plurality of assigned RUs. can do. Further, one STA can transmit a plurality of frames by using the plurality of assigned RUs. At this time, in the plurality of frames, information indicating the AID associated with the assigned RU can be described and transmitted. The AP can transmit different frames to a plurality of AIDs assigned to one STA by using the assigned RUs. The different frames can be frames of different frame types.

Hereinafter, the base station device and the terminal device are collectively referred to as a wireless communication device or a communication device. Further, the information exchanged when one wireless communication device communicates with another wireless communication device is also referred to as data. That is, the wireless communication device includes a base station device and a terminal device.

The wireless communication device has one or both of a function of transmitting and / or a function of receiving PPDU. FIG. 1 is a diagram showing an example of a PPDU configuration transmitted by a wireless communication device. The PPDU corresponding to the IEEE802.11a / b / g standard has a configuration including L-STF, L-LTF, L-SIG and Data frames (MAC Frame, MAC frame, payload, data part, data, information bit, etc.). be. The PPDU corresponding to the IEEE802.11n standard has a configuration including L-STF, L-LTF, L-SIG, HT-SIG, HT-STF, HT-LTF and Data frames. PPDUs corresponding to the IEEE802.11ac standard include some or all of L-STF, L-LTF, L-SIG, VHT-SIG-A, VHT-STF, VHT-LTF, VHT-SIG-B and MAC frames. It is a composition. The PPDUs considered in the IEEE802.11ax standard are RL-SIG, HE-SIG-A, HE-STF, HE- in which L-STF, L-LTF, L-SIG, and L-SIG are repeated in time. It is a configuration including a part or all of the LTF, HE-SIG-B and Data frames. The PPDUs considered in the IEEE802.11be standard are part of the L-STF, L-LTF, L-SIG, RL-SIG, U-SIG, EHT-SIG, EHT-STF, HET-LTF and Data frames or It is a composition that includes everything.

The L-STF, L-LTF and L-SIG surrounded by the dotted line in FIG. 1 have configurations commonly used in the 802.11 standard (hereinafter, L-STF, L-LTF and L-SIG). Collectively referred to as L-header). For example, a wireless communication device corresponding to the IEEE802.11a / b / g standard can appropriately receive the L-header in the PPDU corresponding to the IEEE802.11n / ac standard. The wireless communication device corresponding to the IEEE802.11a / b / g standard can receive the PPDU corresponding to the IEEE802.11n / ac standard as a PPDU corresponding to the IEEE802.11a / b / g standard.

However, since the wireless communication device corresponding to the IEEE802.11a / b / g standard cannot demodulate the PPDU corresponding to the IEEE802.11n / ac standard following the L-header, the transmission address (TA: Transmitter Addless) is used. And the information about the Duration / ID field used to set the receive address (RA: Receiver Header) and NAV cannot be demodulated.

As a method for a wireless communication device corresponding to the IEEE802.11a / b / g standard to appropriately set the NAV (or perform a reception operation for a predetermined period), the IEEE802.11 inserts the Duration information into the L-SIG. It defines the method. Information on the transmission speed in L-SIG (RATE field, L-RATE field, L-RATE, L_DATRATE, L_DATARATE field), information on the transmission period (LENGTH field, L-LENGTH field, L-LENGTH) is 2.1E. A wireless communication device corresponding to the / b / g standard is used to properly set the NAV.

FIG. 2 is a diagram showing an example of a method of Duration information inserted in L-SIG. FIG. 2 shows, as an example, a PPDU configuration corresponding to the IEEE802.11ac standard, but the PPDU configuration is not limited to this. A PPDU configuration corresponding to the IEEE802.11n standard and a PPDU configuration corresponding to the IEEE802.11ax standard may be used. The TXTIME contains information about the length of the PPDU, the aPreambleLength contains information about the length of the preamble (L-STF + L-LTF), and the aPLCPHeaderLength contains information about the length of the PLCP header (L-SIG). L_LENGTH is information on the duration of the Signal Extension is a virtual period set for compatibility IEEE802.11 standard, _{N ops} associated with L_RATE, 1 symbol (symbol, OFDM symbol, etc.) ASymbolLength, It is calculated based on aPLCPServiceLength, which indicates the number of bits included in the PLCP Service field, and aPLCPConvolutionalTailLength, which indicates the number of tail bits of the convolution code. The wireless communication device can calculate L_LENGTH and insert it into L-SIG. Further, the wireless communication device can calculate the L-SIG Duration. The L-SIG Duration shows information about the total period of the PPDU containing L_LENGTH and the Ac and SIFS periods expected to be transmitted from the destination wireless communication device in response.

FIG. 3 is a diagram showing an example of L-SIG Duration in L-SIG TXOP Protection. DATA (frames, payloads, data, etc.) consists of MAC frames and / or parts of PLCP headers. BA is Block Ac or Ac. The PPDU may include L-STF, L-LTF, L-SIG, and may further comprise any or more of DATA, BA, RTS or CTS. In the example shown in FIG. 3, L-SIG TXOP Protection using RTS / CTS is shown, but CTS-to-Self may be used. Here, MAC Duration is a period indicated by the value of Duration / ID field. In addition, the Initiator can transmit a CF_End frame to notify the end of the L-SIG TXOP Protection period.

Next, a method of identifying the BSS from the frame received by the wireless communication device will be described. In order for the wireless communication device to identify the BSS from the received frame, the wireless communication device that transmits the PPDU provides the PPDU with information (BSS color, BSS identification information, a value unique to the BSS) for identifying the BSS. It is preferable to insert it. Information indicating BSS color can be described in HE-SIG-A.

The wireless communication device can transmit L-SIG multiple times (L-SIG Repetition). For example, the wireless communication device on the receiving side receives the L-SIG transmitted a plurality of times by using MRC (Maximum Rio Combining), so that the demodulation accuracy of the L-SIG is improved. Further, the wireless communication device can interpret that the PPDU including the L-SIG is a PPDU corresponding to the IEEE802.11ax standard when the L-SIG is correctly received by the MRC.

The wireless communication device performs a reception operation of a part of the PPDU other than the PPDU (for example, a preamble, L-STF, L-LTF, PLCP header, etc. defined by 802.11) even during the reception operation of the PPDU. (Also called double reception operation). When the wireless communication device detects a part of the PPDU other than the PPDU during the reception operation of the PPDU, the wireless communication device updates a part or all of the destination address, the source address, and the information about the PPDU or the DATA period. Can be done.

Ack and BA can also be referred to as a response (response frame). Further, a probe response, an authentication response, and a connection response can be referred to as a response.
[1. First Embodiment]

FIG. 5 is a diagram showing an example of a wireless communication system according to the present embodiment. The wireless communication system 3-1 includes a wireless communication device 1-1 and wireless communication devices 2-1 to 4. The wireless communication device 1-1 is also referred to as a base station device 1-1, and the wireless communication devices 2-1 to 4 are also referred to as terminal devices 2-1 to 4. Further, the wireless communication devices 2-1 to 4 and the terminal devices 2-1 to 4 are also referred to as a wireless communication device 2A and a terminal device 2A as devices connected to the wireless communication device 1-1. The wireless communication device 1-1 and the wireless communication device 2A are wirelessly connected and are in a state where they can transmit and receive PPDUs to each other. Further, the wireless communication system according to the present embodiment includes a wireless communication system 3-2 in addition to the wireless communication system 3-1. The wireless communication system 3-2 includes a wireless communication device 1-2 and wireless communication devices 2-5 to 8. The wireless communication device 1-2 is also referred to as a base station device 1-2, and the wireless communication devices 2-5 to 8 are also referred to as terminal devices 2-5 to 8. Further, the wireless communication devices 2-5 to 8 and the terminal devices 2-5 to 8 are also referred to as wireless communication devices 2B and terminal devices 2B as devices connected to the wireless communication devices 1-2. The wireless communication system 3-1 and the wireless communication system 3-2 form different BSS, but this does not necessarily mean that the ESS (Extended Service Set) is different. ESS indicates a service set that forms a LAN (Local Area Network). That is, wireless communication devices belonging to the same ESS can be regarded as belonging to the same network from the upper layer. The wireless communication systems 3-1 and 3-2 may further include a plurality of wireless communication devices.

In FIG. 5, in the following description, the signal transmitted by the wireless communication device 2A reaches the wireless transmission device 1-1 and the wireless communication device 2B, but does not reach the wireless communication device 1-2. do. That is, when the wireless communication device 2A transmits a signal using a certain channel, the wireless communication device 1-1 and the wireless communication device 2B determine that the channel is in a busy state, while the wireless communication device 1-2 determines that the channel is in a busy state. The channel is determined to be idle. Further, it is assumed that the signal transmitted by the wireless communication device 2B reaches the wireless transmission device 1-2 and the wireless communication device 2A, but does not reach the wireless communication device 1-1. That is, when the wireless communication device 2B transmits a signal using a certain channel, the wireless communication device 1-2 and the wireless communication device 2A determine that the channel is in a busy state, while the wireless communication device 1-1 determines that the channel is in a busy state. The channel is determined to be idle.

FIG. 6 shows an example of a device configuration of wireless communication devices 1-1, 1-2, 2A and 2B (hereinafter collectively referred to as wireless communication device 10-1 or station device 10-1 or simply station device). It is a figure. The wireless communication device 10-1 includes an upper layer unit (upper layer processing step) 10001-1, an autonomous distributed control unit (autonomous distributed control step) 10002-1, a transmission unit (transmission step) 1003-1, and a reception unit. (Reception step) The configuration includes the 1004-1 and the antenna unit 1005-1.

The upper layer unit 10001-1 is connected to another network and can notify the autonomous distributed control unit 10002-1 of information regarding traffic. The information related to the traffic may be, for example, information addressed to another wireless communication device, or may be control information included in a management frame or a control frame.

FIG. 7 is a diagram showing an example of the device configuration of the autonomous distributed control unit 10002-1. The autonomous distributed control unit 10002-1 includes a CCA unit (CCA step) 10002a-1, a backoff unit (backoff step) 10002b-1, and a transmission determination unit (transmission determination step) 10002c-1. be.

The CCA unit 10002a-1 uses one or both of the information regarding the received signal power received via the radio resource and the information regarding the received signal (including the information after decoding) notified from the receiving unit. , The state of the radio resource can be determined (including the determination of busy or idle). The CCA unit 10002a-1 can notify the backoff unit 10002b-1 and the transmission determination unit 10002c-1 of the state determination information of the radio resource.

The backoff unit 10002b-1 can perform backoff by using the state determination information of the radio resource. The back-off unit 10002b-1 generates a CW and has a countdown function. For example, the CW countdown can be executed when the radio resource status determination information indicates idle, and the CW countdown can be stopped when the radio resource status determination information indicates busy. The back-off unit 10002b-1 can notify the transmission determination unit 10002c-1 of the value of CW.

The transmission determination unit 10002c-1 makes a transmission determination using either or both of the radio resource status determination information and the CW value. For example, when the state determination information of the radio resource indicates idle and the CW value is 0, the transmission determination information can be notified to the transmission unit 1003-1. Further, when the state determination information of the radio resource indicates idle, the transmission determination information can be notified to the transmission unit 1003-1.

The transmission unit 1003-1 is configured to include a physical layer frame generation unit (physical layer frame generation step) 10003a-1 and a wireless transmission unit (wireless transmission step) 1003b-1. The physical layer frame generation unit 10003a-1 has a function of generating a physical layer frame (PPDU) based on the transmission determination information notified from the transmission determination unit 10002c-1. The physical layer frame generation unit 10003a-1 performs error correction coding, modulation, pre-recording filter multiplication, and the like on the transmission frame sent from the upper layer. The physical layer frame generation unit 10003a-1 notifies the wireless transmission unit 1003b-1 of the generated physical layer frame.

FIG. 8 is a diagram showing an example of error correction coding of the physical frame generation unit according to the present embodiment. As shown in FIG. 8, an information bit (systematic bit) series is arranged in the shaded area, and a redundant (parity) bit series is arranged in the white area. Bit interleavers are appropriately applied to the information bits and redundant bits. The physical frame generator can read out the required number of bits as the start position determined according to the value of the redundancy version (RV) for the arranged bit series. By adjusting the number of bits, it is possible to flexibly change the coding rate, that is, puncture. Although four RVs are shown in FIG. 8, the RV options are not limited to specific values in the error correction coding according to the present embodiment. The position of the RV needs to be shared between the station devices.

The physical layer frame generator applies error correction coding to the information bits transferred from the MAC layer, but the unit (encoding block length) for performing error correction coding is not limited to anything. No. For example, the physical layer frame generator may divide the information bit sequence transferred from the MAC layer into information bit sequences of a predetermined length, apply error correction coding to each, and form a plurality of coding blocks. can. When configuring the coding block, a dummy bit can be inserted into the information bit sequence transferred from the MAC layer.

The frame generated by the physical layer frame generation unit 10003a-1 contains control information. The control information includes information indicating to which RU (where the RU includes both frequency resources and spatial resources) the data destined for each radio communication device is located. Further, the frame generated by the physical layer frame generation unit 10037a-1 includes a trigger frame instructing the wireless communication device, which is the destination terminal, to transmit the frame. The trigger frame contains information indicating the RU used when the wireless communication device instructed to transmit the frame transmits the frame.

The radio transmission unit 10003b-1 converts the physical layer frame generated by the physical layer frame generation unit 1003a-1 into a signal in the radio frequency (RF: Radio Frequency) band, and generates a radio frequency signal. The processing performed by the wireless transmission unit 1003b-1 includes digital-to-analog conversion, filtering, frequency conversion from the baseband band to the RF band, and the like.

The receiving unit 1004-1 has a configuration including a wireless receiving unit (radio receiving step) 1004a-1 and a signal demodulation unit (signal demodulation step) 1004b-1. The receiving unit 1004-1 generates information on the received signal power from the RF band signal received by the antenna unit 1005-1. The receiving unit 1004-1 can notify the CCA unit 10002a-1 of the information regarding the received signal power and the information regarding the received signal.

The radio receiving unit 10048a-1 has a function of converting an RF band signal received by the antenna unit 1005-1 into a baseband signal and generating a physical layer signal (for example, a physical layer frame). The processing performed by the wireless receiver 10004a-1 includes frequency conversion processing from the RF band to the baseband band, filtering, and analog-to-digital conversion.

The signal demodulation unit 1004b-1 has a function of demodulating the physical layer signal generated by the radio reception unit 1004a-1. The processing performed by the signal demodulation unit 1004b-1 includes channel equalization, demapping, error correction and decoding, and the like. The signal demodulation unit 1004b-1 can extract, for example, the information included in the physical layer header, the information included in the MAC header, and the information included in the transmission frame from the physical layer signal. The signal demodulation unit 1004b-1 can notify the upper layer unit 10001-1 of the extracted information. The signal demodulation unit 1004b-1 can extract any or all of the information included in the physical layer header, the information included in the MAC header, and the information included in the transmission frame.

The antenna unit 1005-1 has a function of transmitting the radio frequency signal generated by the radio transmission unit 1003b-1 to the radio device 0-1 in the radio space. Further, the antenna unit 1005-1 has a function of receiving a radio frequency signal transmitted from the radio device 0-1.

The wireless communication device 10-1 describes the information indicating the period during which the own device uses the wireless medium in the PHY header and the MAC header of the frame to be transmitted, so that the wireless communication device around the own device is subjected to NAV only during that period. Can be set. For example, the wireless communication device 10-1 can describe information indicating the period in the Duration / ID field or the Length field of the frame to be transmitted. The NAV period set in the wireless communication device around the own device is referred to as the TXOP period (or simply TXOP) acquired by the wireless communication device 10-1. The wireless communication device 10-1 that has acquired the TXOP is referred to as a TXOP acquirer (TXOP holder). The frame type of the frame transmitted by the wireless communication device 10-1 to acquire TXOP is not limited to anything, and may be a control frame (for example, an RTS frame or a CTS-to-self frame) or a data frame. But it's okay.

The wireless communication device 10-1 which is a TXOP holder can transmit a frame between the TXOPs to a wireless communication device other than the own device. When the wireless communication device 1-1 is a TXOP holder, the wireless communication device 1-1 can transmit a frame to the wireless communication device 2A within the period of the TXOP. Further, the wireless communication device 1-1 can instruct the wireless communication device 2A to transmit a frame addressed to the wireless communication device 1-1 within the TXOP period. The wireless communication device 1-1 can transmit a trigger frame including information instructing the wireless communication device 1-1 to transmit a frame to the wireless communication device 2A within the TXOP period.

The wireless communication device 1-1 may secure TXOP for all communication bands (for example, Operation bandwidth) that may transmit frames, or may secure TXOP for a communication band (for example, Transmission bandwidth) that actually transmits frames. It may be secured for a specific communication band (Band) of.

The wireless communication device that gives an instruction to transmit a frame within the TXOP period acquired by the wireless communication device 1-1 is not necessarily limited to the wireless communication device connected to the own device. For example, the wireless communication device is a wireless communication device that is not connected to the own device in order to transmit a management frame such as a reception frame or a control frame such as an RTS / CTS frame to the wireless communication device in the vicinity of the own device. , You can instruct the transmission of frames.

Further, TXOP in EDCA, which is a data transmission method different from DCF, will be described. The IEEE802.11e standard relates to EDCA, and specifies TXOP from the viewpoint of quality of service (QoS) guarantee for various services such as video transmission and VoIP. Services are broadly classified into four access categories: VO (VOice), VI (VIdeo), BE (BestEffort), and BK (BacK ground). Generally, the order is VO, VI, BE, BK from the highest priority. In each access category, there are parameters of CW minimum value CWmin, maximum value CWmax, AIFS (Arbitration IFS) which is a kind of IFS, and TXOP limit which is the upper limit of transmission opportunity. The value is set. For example, CWmin, CWmax, and AIFS, which have the highest priority for voice transmission, are set to values relatively small compared to other access categories, so that the data is prioritized over other access categories. Transmission becomes possible. For example, in VI where the amount of transmission data is relatively large due to video transmission, it is possible to take a longer transmission opportunity than other access categories by setting the TXOP limit large. In this way, the values of the four parameters of each access category are adjusted for the purpose of guaranteeing QoS according to various services.

In the present embodiment, the signal demodulation unit of the station device can perform decoding processing on the received signal in the physical layer and perform error detection. Here, the decoding process includes a decoding process for the error correction code applied to the received signal. Here, the error detection includes error detection using an error detection code (for example, a cyclic redundancy check (CRC) code) given in advance to the received signal, and an error correction code (for example, low density parity) originally provided with an error detection function. Includes error detection by check code (LDPC)). The decoding process in the physical layer can be applied to each coded block.

The upper layer unit transfers the result of decoding the physical layer in the signal demodulation unit to the MAC layer. In the MAC layer, the signal of the MAC layer is restored from the decoded result of the transferred physical layer. Then, in the MAC layer, error detection is performed, and it is determined whether or not the signal of the MAC layer transmitted by the station device that is the transmission source of the received frame can be correctly restored.

The wireless communication device according to the present embodiment implements a procedure (multi-link establishment request, multi-link establishment response) for establishing a plurality of connections (multi-link, Multi-Link), establishes the multi-link, and establishes the multi-link. Can be maintained. Here, maintaining multilink means that frames can be transmitted and received based on predetermined settings for multilink. It is also possible to carry out procedures for changing the multi-link settings (multi-link change request, multi-link reply response) while maintaining the multi-link. It is also possible to cancel the multi-link by performing the procedure for canceling the multi-link (multi-link cancellation request, multi-link cancellation response).

The number of links that make up a multi-link is any number of two or more. The carrier frequency of the link includes the 2.4 GHz band, the 5 GHz band, the 6 GHz band, the 60 GHz band, and the like, and may change according to the laws and regulations of each country.

FIG. 9 shows an outline of the procedure related to the multi-link of the present embodiment by using the wireless communication device 1-1 and the wireless communication device 2-1 as an example of the wireless communication device. In this case, the wireless communication device 2-1 that transmits the multi-link establishment request (9-1) is called a multi-link initiator and is transmitted to the wireless communication device 1-1. The multi-link establishment request may include multi-link capability information (Capability information) of the own device, multi-link operation mode information for requesting establishment, and the like. The multi-link initiator may be a wireless communication device 1-1 instead of the wireless communication device 2-1.

The wireless communication device 1-1 that has received the multi-link establishment request transmits the multi-link establishment response to the wireless communication device 2-1. The multi-link establishment response (9-2) includes the multi-link capability information of the own device, the establishment status information indicating whether or not the multi-link establishment was successful, the multi-link ID used for identifying the multi-link, and the multi-link operation mode. Information and the like may be included. The multi-link ID may be a TID (Traffic ID) or a value based on the TID. The multi-link operation mode information included in the multi-link establishment response includes the multi-link operation mode included in the multi-link establishment request received from the wireless communication device 2-1 and the multi-link operation mode that can be provided by the wireless communication device 1-1. It may be the one finally decided based on. If the establishment status information indicates success, the multilink is established according to the multilink operation mode information included in the multilink establishment response. If the establishment status information indicates a failure, the multilink cannot be established.

The multi-link capability information includes channel information (frequency, bandwidth, etc.) that can be used by the own device, STR availability, frame synchronization availability, multi-link aggregation availability, multi-link switch availability, multi-link TXOP (maximum value, minimum value, etc.). ) And other information may be included. Multi-link operation mode information includes channel information (frequency, bandwidth, etc.) of each link that constitutes multi-link, multi-link TXOP limit, multi-link aggregation, multi-link switch, frame synchronization, frame asynchronous, STR, non-STR, etc. May be included.

Multilink TXOP is a parameter that works effectively only at the time of MLO. The multi-link TXOP, which is a parameter included in the multi-link capability information, has several fields, and the maximum value (value reproduced by the laws and regulations of each country, etc.), recommended value, and minimum value (multi-link) supported by the own device are provided. Information such as (values that must be secured at a minimum for the service guarantee of the initiator, etc.) may be included. If the value of the multi-link TXOP included in the multi-link capability information is set to a special value such as 0 or NULL, the multi-link TXOP may be invalidated and only the TXOP according to the conventional method may be secured. ..

The multi-link TXOP limit included in the multi-link operation mode information of the multi-link establishment response stores a value determined by negotiation between the wireless communication device 1-1 and the wireless communication device 2-1. Specifically, both the value of the multi-link TXOP included in the multi-link capability information of the wireless communication device 2-1 and the multi-link TXOP included in the multi-link capability information of the wireless communication device 1-1 are satisfied. Will be decided. The wireless communication device 1-1 and the wireless communication device 2-1 that established the multi-link were determined within a range not exceeding the multi-link TXOP limit when the transmission right on the wireless medium was secured through carrier sense or the like. The multi-link TXOP section can occupy the radio medium and can transmit one or more PPDU frames.

The established multi-link multi-link TXOP does not know anything other than the wireless communication device 1-1 and the wireless communication device 2-1. However, as described above, the wireless communication device describes the information indicating the period during which the own device uses the wireless medium in the PHY header and the MAC header of each PPDU frame to be transmitted, so that the wireless communication device around the own device can be used. Can be set to NAV only during the relevant period.

The multi-link TXOP limit is a parameter different from the TXOP limit defined in the IEEE802.11e standard. At the time of negotiation between the wireless communication device 1-1 and the wireless communication device 2-1 described above, the multi-link TXOP limit may be determined in consideration of the TXOP limit defined in the IEEE802.11e standard. Specifically, according to the value of the multi-link TXOP included in the multi-link capability information of the wireless communication device 2-1 and the multi-link TXOP included in the multi-link capability information of the wireless communication device 1-1, according to the IEEE802.11e standard. It is determined so as to satisfy the set TXOP limit condition. Alternatively, invalidate the value of the multi-link TXOP included in the multi-link capability information or the multi-link TXOP limit included in the multi-link operation mode information to a special value such as 0 or NULL, and comply with the IEEE802.11e standard. The set TXOP limit may be enabled. This makes it possible to set a multi-link TXOP limit suitable for each access category of VO, VI, BK, and BE.

The number of multilinks established between the wireless communication device 1-1 and the wireless communication device 2-1 is not limited to one, and it is possible to establish a plurality of multilinks. Each multi-link can also be identified by the multi-link ID.

The established multi-link will be maintained thereafter. When changing the operation mode of the multi-link, it is also possible to carry out the procedure of the multi-link change request (9-3) while maintaining the multi-link connection. The time length of the multi-link TXOP limit can also be changed by the multi-link change request. FIG. 9 shows a multi-link change request from the wireless communication device 2-1 which is a multi-link initiator to the wireless communication device 1-1, and a multi-link change response (9-) from the wireless communication device 1-1 to the wireless communication device 2-1. Although it is an example of returning 4), conversely, a multi-link change request may be made from the wireless communication device 1-1 which is not a multi-link initiator, and the wireless communication device 2-1 may return a multi-link change response. The multi-link change response contains change status information indicating whether or not the change has been accepted, and it is possible to know whether or not the change such as the operation mode has succeeded or failed.

It can be canceled by sending a multi-link cancellation request (9-5). By including the multi-link ID in the multi-link cancellation request, the multi-link to be canceled can be indicated. By not including the multi-link ID in the multi-link cancellation request or setting the multi-link ID to a special value such as NULL, a plurality of wireless communication devices 1-1 and the wireless communication device 2-1 are established. You may cancel the multi-link at once. In FIG. 9, the wireless communication device 2-1 which is the multi-link initiator requests the wireless communication device 1-1 to release the multi-link, and the wireless communication device 1-1 requests the wireless communication device 2-1 to release the multi-link (9-). 6) In this example, conversely, a multi-link cancellation request may be made from a wireless communication device 1-1 that is not a multi-link initiator. The multi-link release response may include release status information indicating whether or not the release was accepted.

The multi-link establishment request may be included in the frame for the connection (Association) procedure or the reconnection (Reassociation) procedure, or it may be dedicated at the required timing after the connection (Association) procedure or the reconnection (Reassociation) procedure. It may be a procedure using the frame of. The multi-link release request may be included in the dissociation (Disassociation or Deauthentication) procedure, or may be separately requested at the required timing before the dissociation (Disassociation or Deauthentication) procedure.

Information related to multi-link such as multi-link capability information and multi-link operation mode may be included in a management frame such as Beacon or ProbeResponse transmitted by the wireless communication device 1-1. Information related to multi-link such as multi-link capability information and multi-link operation mode may be treated as MIB (Management Information Base) information.

FIG. 10 shows an example of communication according to this embodiment. The wireless communication device 2-1 according to the present embodiment establishes a multi-link with the wireless communication device 1-1. FIG. 10 is an example of a multi-link composed of three links (link 1, link 2, link 3), and each link has a different carrier frequency. For example, link 1 has a frequency in the 2.4 GHz band and link 2. Is a frequency of W52 (5.15 to 5.25 GHz) in the 5 GHz band, and link 3 is a frequency of W53 (5.25 to 5.35 GHz) in the 5 GHz band. FIG. 10 shows an example in which PPDU transmission is performed in frame synchronization on the time axis for all links (link 1, link 2, link 3), but PPDU transmission may be performed frame asynchronously as shown in FIG. The frame synchronization referred to here refers to a state in which the head (left end) or the end (right end) of each PPDU transmitted on all links, or the head and the end are aligned. In the example of PPDU that is transmitted first in each link in the multi-link TXOP section 10-3, the beginning (left end) is aligned like 10-1 and the end (right end) is aligned like 10-4. Point to. Frame asynchronous refers to a state other than frame synchronization.

When the wireless communication device 1-1 and the wireless communication device 2-1 that have established the multi-link secure the transmission right on the wireless medium through carrier sense or the like, the section of the multi-link TXOP may occupy the wireless medium. It becomes possible to transmit one or more PPDU frames. Within the multi-link TXOP section, carrier sense does not have to be performed each time PPDU is transmitted, but carrier sense is not prohibited. The multi-link TXOP starts with reference to the first PPDU transmission timing of each link constituting the multi-link. In the case of FIG. 10, the PPDU transmission on each link is frame-synchronized, and the time 10-1 which is the PPDU transmission start timing on all links is an example of the multi-link TXOP start time. In the case of FIG. 11, the PPDU transmission at each link is frame asynchronous, the link 1 first transmits the PPDU 11-20 in the multi-link TXOP section 11-3, and the time 11-1 is the multi-link TXOP start time. It is an example.

The frame synchronization shown in FIG. 10 is regarded as a special case in the case of the frame asynchronous shown in FIG. 11, and will be mainly described with reference to FIG. 11 thereafter. Since the established multi-link multi-link TXOP is determined by the negotiation between the wireless communication device 1-1 and the wireless communication device 2-1 at the time of establishing the multi-link, other wireless communication devices are unknown. However, as described above, the wireless communication device describes the information indicating the period during which the own device uses the wireless medium in the PHY header and the MAC header of each PPDU frame to be transmitted, so that the wireless communication device around the own device can be used. Can be set to NAV only during the relevant period. That is, in FIG. 11, in the PHY header and MAC header of each PPDU transmitted by each link constituting the multilink, information indicating the time until the end of the multilink TXOP starting from the PPDU is described. .. For example, for PPDU11-21, time information corresponding to securing NAV from time 11-4 to time 11-2 is described, and for PPDU11-22, NAV is secured from time 11-5 to time 11-2. Time information corresponding to that is described. The same applies to the synchronous frame transmission of FIG.

When the period from PPDU transmission to BA reception, as shown in FIGS. 10 and 11, is defined as the minimum unit of the multi-link communication sequence, the multi-link TXOP section for each minimum unit is defined with the multi-link TXOP limit as the upper limit. It may change each time. That is, in FIG. 11, in the multi-link once established, the length of the multi-link TXOP section 11-3 may be different for each communication. The same applies to the case of FIG. 10.

The BPDU is transmitted from the wireless communication device 2-1 in the direction of the wireless communication device 1-1 (called Uplink (UL)), and after the PPDU transmission is completed, a BAR (Block Ack Request) requesting a response frame is transmitted. Then, a response frame, in this example, BA (BlockAck) is transmitted from the wireless communication device 1-1 in the direction of the wireless communication device 2-1 (referred to as Downlink (DL)).

In the multi-link TXOP section, the wireless communication device 2-1 does not switch between transmission and reception, except for the response frame reception at the end of the section, and can only perform frame transmission. As one method, for example, the wireless communication device 2-1 is not an Immediate Block Ack method in which a response frame is received after SIFS has elapsed after PPDU transmission, but a Delayed Block Ack method in which a response frame is received at an arbitrary timing after PPDU transmission. May be set to use. In this case, the wireless communication device 1-1 that has received the PPDU from the wireless communication device 2-1 does not transmit the response frame after SIFS. The wireless communication device 2-1 completes transmission of all the planned PPDUs in one multi-link TXOP section, and then all the links (link 1, link 2, link) to the wireless communication device 1-1. By transmitting the BAR (BlockAckRequest) (11-24, 11-28, 11-32) at the same time in 3), the response frame BA (11-25) at the same time from the wireless communication device 1-1 , 11-29, 11-30) can be completed.

Further, the value and end time of the multi-link TXOP in the established multi-link are known not only to the wireless communication device 2-1 but also to the wireless communication device 1-1. Therefore, there may be a procedure in which the BAR transmission from the wireless communication device 2-1 to the wireless communication device 1-1 is skipped and the wireless communication device 1-1 only performs BA transmission to the wireless communication device 2-1. In this case as well, it is possible to avoid the STR state.

Although it is desirable that the difference in BAR transmission timing and the difference in BA transmission timing in each link are exactly the same, it is sufficient that the difference is within a specific time (for example, SIFS). As a result, the STR state is not reached.

It is also possible to shorten the length of the multi-link TXOP that was initially secured. For example, in FIG. 11, although four PPDUs are transmitted at link 1, it is equivalent to maintaining the initially secured multi-link TXOP even though the transmission of the last fourth PPDU is canceled. The time spent is wasted without using any wireless communication device. Therefore, as shown in FIG. 12, it is shortened to an arbitrary timing within the originally planned multi-link TXOP time (12-3), for example, time 12-4, and updated to a new multi-link TXOP time (12-5). You may. Specifically, the BA (12-25, By setting the time 12-4 to 12-29, 12-33), the NAV can be updated and the wireless medium can be opened so that the wireless communication device around the own device can be used. In this way, the BAR transmission on all links is advanced by the same time, and the PHY header of the BAR is updated so as to secure the time until the scheduled completion time of BA reception. This makes it possible to effectively utilize the free time that accompanies the cancellation of PPDU transmission.

That is, according to the present embodiment, when the transmission right on the wireless medium is secured through carrier sense or the like, the multi-link TXOP with the upper limit of the multi-link TXOP limit can be secured as the transmission opportunity, and the transmission opportunity can be secured. It is also possible to transmit not only one PPDU but also a plurality of PPDUs, and it is possible to transmit a large capacity frame at a time with a small transmission delay. The STR-capable wireless communication device may use the Immediate Block Ack method (a method of opening SIFS and transmitting BA after receiving PPDU) as the response frame method, but the overhead is reduced by using the Delayed Block Ack method. It is possible to increase the number of PPDUs transmitted during the multi-link TXOP period. In addition, the wireless communication device that does not support STR is set to use the Delayed Block Ack method, and the reception of the response frame is completed by the end time of the multi-link TXOP reserved for the multi-link communication. By transmitting BAR at the same time for all the links constituting the multi-link, the STR state can be avoided.

It is also possible to request a response frame for all links (link 1, link 2, link 3) with one of the links constituting the multi-link, for example, link 1. For example, FIG. 11 shows a case where the scheduled PPDU transmission is completed earlier in the link 2 and the link 3 than in the link 1, but the link 2 and the link 3 are uselessly wireless media until the end of the multi-link TXOP. Can be secured.

Therefore, as shown in FIG. 13, for the link 2 and the link 3, the PHY of the PPDU transmitted on each link so as to secure the NAV until the final PPDU transmission scheduled to be transmitted in the multi-link TXOP is completed. Set the TXOP value of the header and MAC header. Specifically, for example, when the very first PPDU13-26 on the link 2 is transmitted, the wireless medium of the link 2 is set to be released at time 13-5, and the first PPDU13- on the link 3 is set. At the time of transmission of 30, the radio medium of the link 3 is set to be released at the time 13-7. FIG. 13 shows an example in which the PPDU (13-26, 13-30) transmitted first (leftmost) in the link 2 and the link 3 is updated to shorten the NAV, but the same multi-link. If it is a PPDU transmitted by TXOP, NAV may be updated by another PPDU. By this method, the wireless medium used by the link 2 and the link 3 is released at an early stage, and another wireless communication device can transmit and receive using the wireless medium.

Further, the link 2 and the link 3 can be entrusted with the reception of the response frame to the link 1 which has been subjected to PPDU transmission to the end among all the links (link 1, link 2, link 3) in the multi-link TXOP. .. Specifically, by including the request of other links (link 2 and link 3 in this example) in the BAR 13-24 of the link 1, the information of the link 1, the link 2 and the link 3 is included in the response frame BA 13-25. Will be included. Alternatively, in the wireless communication device 1-1, since the transmission end time of all PPDUs of all the links is known not only to the wireless communication device 2-1 but also to the wireless communication device 1-1, the wireless communication device 2-1 The procedure may be such that the transmission of the BAR 13-24 to the wireless communication device 1-1 is skipped, and the wireless communication device 1-1 only transmits the BA13-25 to the wireless communication device 2-1. By this method, the response frame reception on the link 2 and the link 3 does not occur during the transmission of the link 1, that is, the STR state can be avoided.

It is also possible to apply the multi-link TXOP not to all links (link 1, link 2, link 3) but to only some links. As shown in FIG. 14, for example, when link 1 transmits only a small amount of PPDU, but link 2 and link 3 transmit a large amount of PPDU, it becomes less meaningful to secure a common multi-link TXOP for all links. This is because the link 1 having a small number of PPDU transmissions causes a problem of wastefully consuming the wireless medium. This problem can be avoided by not using the multi-link TXOP for the link 1 and using the multi-link TXOP for the link 2 and the link 3.

Of course, in this case, link 1 needs to be STR capable. This is because when the response frame BA is received at the link 1, the link 2 and the link 3 may be in a state of transmitting PPDU, and an STR state may occur. Factors that allow STR of wireless communication devices include (A) factors that depend on the capabilities of hardware such as ICs, and (B) factors that depend on the capabilities of RF components such as filters when using near frequencies (for example, W52). There are factors of interference that occur in the combination of W53). In this example, link 1 is 2.4 GHz, link 2 is W52, and link 3 is W53. Due to the interference factor (B), link 2 and link 3 interfere with each other and STR is not possible, but link 1 is 2. Since it is .4 GHz, the influence of interference from the 5 GHz band is small, and STR is possible. When STR is possible with some combinations of links in this way, depending on the use case, multi-link TXOP is not applied to all links (link 1, link 2, link 3), and only some links are available. It is also possible to use the wireless medium efficiently as a whole by applying it to.

FIG. 15 (a) is an example of a table showing whether or not STR is possible for each link combination for the wireless communication device 1-1 and FIG. 15 (b) for the wireless communication device 2-1. A circle (○) means that STR is possible, a cross mark (×) means that STR is not possible, and a diagonal line means that the combination thereof does not actually exist and is invalid. The wireless communication device 1-1 can be STRed between all links, the wireless communication device 2-1 can be STRable for the combination of link 1 and link 2, STR possible for the combination of link 1 and link 3, and link 2 and link. The combination of 3 indicates that STR is not possible.

At the time of establishing the multi-link, the wireless communication device 2-1 of the multi-link initiator transmits the information corresponding to FIG. 15 (b) to the wireless communication device 1-1, and the wireless communication device 1-1 has its own STR availability information (here). Then, the information corresponding to the table of FIG. 15 (c) is generated by taking an AND with FIG. 15 (a), included in the operation mode information of the multi-link response, and notified to the wireless communication device 2-1. In other words, as a result of negotiation, both wireless communication devices can support, the combination of link 1 and link 2 can be STR, the combination of link 1 and link 3 can be STR, and the combination of link 2 and link 3 cannot be STR. It becomes multi-link communication. In the above, it is an example of deriving FIG. 15 (c) from the AND of FIGS. 15 (a) and 15 (b), but depending on the use case, the OR of FIGS. 15 (a) and 15 (b), etc. Other arithmetic operations may be used.

Whether or not STR is possible can be expressed between each link of the multi-link established as shown in FIG. 15, but between the channel information (determined by the carrier frequency, bandwidth, etc.) supported by each wireless communication device as shown in FIG. It can also be expressed as information. In FIG. 16, channel 1 is STRable with all other channels, channel 2 is STRable with channel 1 and channel 5, channel 3 is STRable with channel 1 and channel 5, and channel 4 is STRable with channel 1 and channel 5. , Channel 5 expresses that STR is possible with all other channels, and STR is not possible with other channel combinations.

Note that the link combinations and channel combinations are duplicated in FIGS. 15 (a), 15 (b), 15 (c), and 16 (a). The combination may be removed and expressed as shown in FIGS. 15 (d), 15 (e), 15 (f), and 16 (b).

As described above, the information indicating whether or not STR is possible as shown in FIGS. 15 and 16 may be included in the multi-link establishment request or the multi-link establishment response, but by including it in the notification information such as Beacon or the Probe Response, it may be included. The STR capability of the own device may be notified. As a method of expressing STR possibility information, there is a bitmap or the like. Specifically, STR possible is expressed as "1", STR not possible is expressed as "0", and for FIG. 15 (c), STR possible / not information is expressed as [1,1] for link 1 and [1] for link 2. , 0] and link 3 may be expressed as [1,0], and may be collectively expressed as [1,1,1,0,1,0]. This can be calculated by scanning from left to right and from top to bottom in the table of FIG. 15 (c), ignoring the shaded areas. In the case of FIG. 16 (a), [1,1,1,1,1,0,0,1,1,0,0,1,1,0,0,1,1,1,1,1] Become.

However, since the table in FIG. 15 (c) is redundant, the table in FIG. 15 (f) is used to scan from left to right and from top to bottom, ignoring the shaded areas [1,. Information expressed as 1,0] may be notified. In the case of FIG. 16B, the expression is [1,1,1,1,0,0,1,0,1,1]. The representation method of these bitmaps is an example, and other representation methods may be used as long as they have the same meaning.
[2. Common to all embodiments]

The program that operates in the wireless communication device according to one aspect of the present invention is a program that controls a CPU or the like (a program that causes a computer to function) so as to realize the functions of the above embodiment according to one aspect of the present invention. The information handled by these devices is temporarily stored in RAM at the time of processing, then stored in various ROMs and HDDs, and is read, corrected, and written by the CPU as needed. The recording medium for storing the program includes a semiconductor medium (for example, ROM, non-volatile memory card, etc.), an optical recording medium (for example, DVD, MO, MD, CD, BD, etc.), a magnetic recording medium (for example, magnetic tape, etc.). It may be any of flexible disks, etc.). In addition, by executing the loaded program, not only the functions of the above-described embodiment are realized, but also by processing in collaboration with the operating system or other application programs based on the instructions of the program, the present invention In some cases, the function of the invention is realized.

When distributing to the market, the program can be stored and distributed in a portable recording medium, or transferred to a server computer connected via a network such as the Internet. In this case, the storage device of the server computer is also included in one aspect of the present invention. Further, a part or all of the communication device in the above-described embodiment may be realized as an LSI which is typically an integrated circuit. Each functional block of the communication device may be individually chipped, or a part or all of them may be integrated into a chip. When each functional block is made into an integrated circuit, an integrated circuit control unit for controlling them is added.

Further, the method of making an integrated circuit is not limited to LSI, but may be realized by a dedicated circuit or a general-purpose processor. Further, when an integrated circuit technology that replaces an LSI appears due to advances in semiconductor technology, it is also possible to use an integrated circuit based on this technology.

The invention of the present application is not limited to the above-described embodiment. The wireless communication device of the present invention is not limited to application to mobile station devices, and is not limited to application to mobile station devices, but is stationary or non-movable electronic devices installed indoors and outdoors, such as AV devices, kitchen devices, cleaning / washing. Needless to say, it can be applied to equipment, air conditioning equipment, office equipment, vending machines, and other living equipment.

Although the embodiment of the present invention has been described in detail with reference to the drawings, the specific configuration is not limited to this embodiment, and the design and the like within a range not deviating from the gist of the present invention are also claimed. Included in the range.

One aspect of the present invention is suitable for use in communication devices and communication methods.

1-1, 1-2 Access point device 2-1 to 8 Station device 3-1, 3-2 Management range 10001-1 Upper layer section 10002-1 Autonomous distributed control section 10002a-1 CCA section 10002b-1 Backoff section 10002c-1 Transmission judgment unit 1003-1 Transmitter unit 10038-1 Physical layer frame generation unit 1003b-1 Wireless transmission unit 1004-1 Receiver unit 1004000-1 Wireless reception unit 1004000b-1 Signal demodulation unit 1005-1 Antenna unit 9-1 ~ 6 Multilink Related Signals 10-1 ~ 4, 11-1 ~ 11-6, 12-1 ~ 12-6, 13-1 ~ 13-7 Times Related to Multilink TXOP 10-20 ~ 10-22 , 11-20-11-32, 13-20-13-31 PPDU (including BAR and BA)

Claims (7)

1. A receiver that receives control information related to multiple connections (multi-link),
   A frame transmission unit for transmitting a frame associated with the plurality of connections is provided, and the plurality of connections are composed of two or more connections.
   The control information includes information related to transmission opportunities.
   The frame transmitter is
   The frame can be transmitted to the transmission opportunity based on the information related to the transmission opportunity.
   Wireless communication device.
2. In all the connections that make up the multiple connections
   Receive a response frame,
   A response request frame is transmitted so that the transmission opportunity ends when the reception of the response frame is completed.
   The wireless communication device according to claim 1.
3. Shortly update the transmission opportunity before the end of the transmission opportunity,
   The wireless communication device according to claim 1.
4. At least one connection that constitutes the plurality of connections and abandons the transmission opportunity prior to the end of the transmission opportunity.
   Have another connection that maintains the transmission opportunity send a response request frame,
   The wireless communication device according to claim 1.
5. The transmission opportunity
   It is valid only for a part of the connections constituting the plurality of connections.
   The wireless communication device according to claim 1.
6. The control information related to the plurality of connections (multi-link) is
   Included in the control frame for establishing the multiple connections,
   The wireless communication device according to claim 1.
7. The control information related to the plurality of connections (multi-link) is
   Included in the notification frame transmitted by the access point device,
   The wireless communication device according to claim 1.

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