JP2020171032A - Data communication method and related device - Google Patents

Abstract

To provide a data communication method and a related device.SOLUTION: A data communication method includes the steps of: constructing a beacon frame by an access device, the beacon frame including a newly added field, and the newly added field representing a plurality of data guard intervals supported by the access device; and selecting, by a terminal, a usable guard interval length according with data interval lengths supported by the terminal from the beacon frame, and broadcasting the beacon frame by the access device so as to be able to perform data communication with the access device by using the usable guard interval length. The use of the invention enables data communication between the access device and a terminal in the case where the access device supports a plurality of data guard interval lengths.SELECTED DRAWING: Figure 1

Description

This application is a continuation of International Application No. PCT / CN 2014/087403 filed on September 25, 2014, which is incorporated herein by reference in its entirety.
The present invention relates to the field of data communication technology, and more particularly to data communication methods and related devices.

With the development of communication technology, wireless premises network (WLAN) technology based on the IEEE 802.11 standard has been widely applied. Currently, various mainstream WLAN standards (such as 802.11n and 802.11ac) introduce guard intervals (GIs) to eliminate intersymbol interference caused by channel delay spread. In the process of the terminal communicating with the access device, the terminal needs to choose an appropriate guard interval length to minimize intersymbol interference. The GI length used in the 802.11ac standard is 0.8us. In the process of data communication between the access device and the terminal, AP and STA use a preamble GI length of 0.8us and a data GI length of 0.8us.

The IEEE officially proposed the next-generation WLAN standard, High Efficiency WLAN (HEW), in May 2013, but the HEW standard is called 802.11ax. HEW standardization work proposes to offer more options for GI length, including GI lengths such as 3.2us, 2.4, 1.6us, 1.2us, 0.8us, 0.4us. Has been done. HEW solutions with multiple selectable GI lengths currently have no way to set the GI length for data communication between the terminal and the access device in HEW.

Embodiments of the present invention provide data communication methods and related devices capable of implementing data communication between an access device and a terminal when the access device supports a plurality of data guard interval lengths.

A first aspect of the present invention provides a data communication method, wherein the method is a step of constructing a beacon frame by an access device, the beacon frame including a newly added field, and a newly added field. Represents multiple data guard interval lengths supported by the access device,
Allowing the terminal to perform data communication with the access device by selecting an available guard interval length from the beacon frame that matches the data guard interval length supported by the terminal and using the available guard interval length. , The step that the access device broadcasts the beacon frame,
including.

Based on the first aspect, in the first feasible implementation method, the beacon frame contains at least one element, and the specific element of at least one element carries the newly added field and is a specific element. Is an existing element or a newly added element.

Based on the first feasible implementation of the first aspect, in the second feasible implementation, the newly added fields include indicator values corresponding to each preset bandwidth. The indicator value represents the minimum data guard interval length of all data guard interval lengths supported by the access device within the preset bandwidth, or the newly added field represents each preset data guard interval. Contains long indicator bits, which are used to indicate whether the access device supports preset data guard interval lengths, or newly added fields within each preset bandwidth. Each preset data guard interval length of the indicator bit is included, and the indicator bit is used to indicate whether the access device supports a preset data guard interval length within the preset bandwidth.

Based on the first aspect, in the third feasible implementation method, after the step of constructing the beacon frame by the access device, the method
It further includes the step of separately encapsulating the beacon frame into the first standard protocol data unit and the second standard protocol data unit by the access device.
The step of broadcasting the beacon frame by the access device is
It includes a step of broadcasting a beacon frame encapsulated in a first standard protocol data unit and a beacon frame encapsulated in a second standard protocol data unit by an access device.

Based on the third feasible implementation of the first aspect, the plurality of data guard interval lengths supported by the access device in the fourth feasible implementation are supported by the access device in the first standard. It includes a data guard interval length and a data guard interval length supported by the access device in the second standard, and the access device encapsulates the beacon frame separately in the first standard protocol data unit and the second standard protocol data unit. The step to change is
The step of obtaining the maximum data guard interval length in the data guard interval length supported by the access device in the first standard by the access device and determining the maximum data guard interval length as the first alternative data guard interval length.
The step of obtaining the maximum data guard interval length in the data guard interval length supported by the access device in the second standard by the access device and determining the maximum data guard interval length as the second alternative data guard interval length.
With the first alternate data guard interval length and the second alternate data guard interval length, the access device encapsulates the beacon frame separately in the first standard protocol data unit and the second standard protocol data unit, and
including.

Based on the fourth feasible implementation method of the first aspect, in the fifth feasible implementation method, the first standard protocol data unit includes the preamble and bearer data, and the bearer data includes the beacon frame. , The preamble guard interval length and the bearer data guard interval length are the first alternative data guard interval lengths.

Based on the fourth feasible implementation of the first aspect, in the sixth feasible implementation, the second standard protocol data unit is a legacy preamble, a high efficiency radio local area network preamble, and bearer data. The guard interval length of the legacy preamble, the guard interval length of the high-efficiency wireless local area network preamble, and the guard interval length of the bearer data are, respectively, the second alternative data guard interval length, or
The second standard protocol data unit contains the legacy preamble, the highly efficient radio local area network preamble, and the bearer data, and the guard interval length of the legacy preamble is the first alternative data guard interval length, which is the highly efficient radio local area. The guard interval length of the network preamble and the guard interval length of the bearer data are the second alternative data guard interval length, or
The second standard protocol data unit contains the high efficiency wireless local area network preamble and bearer data, and the guard interval length of the high efficiency wireless local area network preamble and the guard interval length of the bearer data are both the second alternative data guard interval. It is long.

Based on the fourth feasible implementation of the first aspect, in the seventh feasible implementation, the beacon frame encapsulated in the first standard protocol data unit and the second standard protocol data unit. Before the step of the access device broadcasting the encapsulated beacon frame, the method is
It further includes a step in which the access device adds a calculated field used to indicate the transmission time of the second standard protocol data unit to the first standard protocol data unit.
The step in which the access device broadcasts the beacon frame encapsulated in the first standard protocol data unit and the beacon frame encapsulated in the second standard protocol data unit is
With the step of broadcasting the first standard protocol data unit containing the calculated field during a preset period of time by the access device.
A step in which the access device broadcasts a second standard protocol data unit at the transmission time indicated by the calculated field,
including.

A second aspect of the present invention provides a data communication method, wherein the method is a step in which the terminal acquires a beacon frame broadcast by the access device, wherein the beacon frame includes a newly added field. The added fields represent the multiple data guard interval lengths supported by the access device, the steps and
A step in which the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from multiple data guard interval lengths supported by the access device.
Steps in which the terminal communicates data with the access device by using the available guard interval length,
including.

Based on the second aspect, in the first feasible implementation method, the beacon frame is encapsulated in a first standard protocol data unit and a second standard protocol data unit, and the access device has a preset period. The first standard protocol data unit is transmitted to, and the first standard protocol data unit contains a calculated field used to indicate the transmission time of the second standard protocol data unit.

Based on the first feasible implementation method of the second aspect, in the second feasible implementation method, the step of the terminal acquiring the beacon frame broadcast by the access device is
A step in which the terminal acquires the first standard protocol data unit broadcast by the access device and analyzes the beacon frame from the first standard protocol data unit, or
A step in which the terminal acquires the second standard protocol data unit broadcast by the access device and analyzes the beacon frame from the second standard protocol data unit, or
The terminal acquires the first standard protocol data unit broadcast by the access device, determines the transmission time of the second standard protocol data unit from the arithmetic field in the first standard protocol data unit, and determines the transmission time of the second standard protocol data unit according to the transmission time. Steps to get the standard protocol data unit and analyze the beacon frame from the second standard protocol data unit,
including.

A third aspect of the present invention provides an access device, the access device being a construction module configured to build a beacon frame, the beacon frame including a newly added field. The fields represented by the construction module represent the multiple data guard interval lengths supported by the access device.
A transceiver module configured to broadcast beacon frames and perform data communication with terminals,
including.

According to the third aspect, in the first feasible implementation, the beacon frame contains at least one element, the specific element of at least one element carries the newly added field, and the specific element , An existing element or a newly added element.

Based on the first feasible implementation of the third aspect, in the second feasible implementation, the newly added fields include indicator values corresponding to each preset bandwidth. The indicator value represents or represents the minimum data guard interval length of all data guard interval lengths supported by the access device within the preset bandwidth.
The newly added field contains an indicator bit for each preset data guard interval length, which is used to indicate whether the access device supports the preset data guard interval length, or ,
The newly added field contains an indicator bit for each preset data guard interval length within each preset bandwidth, which indicates the preset data guard interval within the bandwidth preset by the access device. Used to indicate whether length is supported.

Based on the third aspect, in a third feasible implementation, the access device is configured to encapsulate the beacon frame separately in a first standard protocol data unit and a second standard protocol data unit. Includes additional encapsulation modules
The transceiver module is specifically configured to broadcast a beacon frame encapsulated in a first standard protocol data unit and a beacon frame encapsulated in a second standard protocol data unit.

Based on the third feasible implementation of the third aspect, the plurality of data guard interval lengths supported by the access device in the fourth feasible implementation are supported by the access device in the first standard. The encapsulation module contains a data guard interval length and a data guard interval length supported by the access device in the second standard.
A first configured to obtain the maximum data guard interval length of the data guard interval lengths supported by the access device in the first standard and determine the maximum data guard interval length as the first alternative data guard interval length. Acquisition unit and
A second standard configured to obtain the maximum data guard interval length of the data guard interval lengths supported by the access device in the second standard and determine the maximum data guard interval length as the second alternative data guard interval length. Acquisition unit and
Encapsulation configured to encapsulate the beacon frame separately into the first standard protocol data unit and the second standard protocol data unit by the first alternate data guard interval length and the second alternate data guard interval length. With the unit
including.

Based on the fourth feasible implementation method of the third aspect, in the fifth feasible implementation method, the first standard protocol data unit includes the preamble and bearer data, and the bearer data includes the beacon frame. , The preamble guard interval length and the bearer data guard interval length are the first alternative data guard interval lengths.

Based on the fourth feasible implementation of the third aspect, in the sixth feasible implementation, the second standard protocol data unit is the legacy preamble, the high efficiency radio local area network preamble, and the bearer data. The guard interval length of the legacy preamble, the guard interval length of the high-efficiency wireless local area network preamble, and the guard interval length of the bearer data are, respectively, the second alternative data guard interval length, or
The second standard protocol data unit contains the legacy preamble, the highly efficient radio local area network preamble, and the bearer data, and the guard interval length of the legacy preamble is the first alternative data guard interval length, which is the highly efficient radio local area. The guard interval length of the network preamble and the guard interval length of the bearer data are the second alternative data guard interval length, or
The second standard protocol data unit contains the high efficiency wireless local area network preamble and bearer data, and the guard interval length of the high efficiency wireless local area network preamble and the guard interval length of the bearer data are both the second alternative data guard interval. It is long.

In the seventh feasible mounting method, the access device is based on the fourth feasible mounting method of the third aspect.
It further includes a processing module configured to add a calculated field used to indicate the transmission time of the second standard protocol data unit to the first standard protocol data unit.
The transceiver module is specifically configured to broadcast a first standard protocol data unit containing arithmetic fields for a preset period of time.
The transceiver module is further configured to broadcast a second standard protocol data unit at the transmit time indicated by the calculated field.

A fourth aspect of the present invention provides a terminal, which is a terminal.
A transceiver module configured to capture a beacon frame broadcast by an access device, where the beacon frame contains a newly added field, and the newly added field is a plurality of fields supported by the access device. A transceiver module that represents the data guard interval length and
A selection module configured to select an available guard interval length that matches the data guard interval length supported by the terminal from multiple data guard interval lengths supported by the access device.
Including
The transceiver module is further configured to perform data communication with the access device by using the available guard interval length.

Based on the fourth aspect, in the first feasible implementation method, the beacon frame is encapsulated in the first standard protocol data unit and the second standard protocol data unit, and the access device is provided with a preset period. The first standard protocol data unit is transmitted to, and the first standard protocol data unit contains a calculated field used to indicate the transmission time of the second standard protocol data unit.

Based on the first feasible implementation of the fourth aspect, in the second feasible implementation, the transceiver module acquires the first standard protocol data unit broadcast by the access device and the first. Specifically configured to parse beacon frames from standard protocol data units, or
The transceiver module is specifically configured to acquire a second standard protocol data unit broadcast by the access device and parse the beacon frame from the second standard protocol data unit, or
The transceiver module acquires the first standard protocol data unit broadcast by the access device, determines the transmission time of the second standard protocol data unit from the arithmetic field in the first standard protocol data unit, and determines the transmission time of the second standard protocol data unit according to the transmission time. It is specifically configured to acquire two standard protocol data units and analyze the beacon frame from the second standard protocol data unit.

In an embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, the newly added field representing a plurality of data guard interval lengths supported by the access device. The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frame broadcast by the access device, and the available guard interval. Communicate with the access device by using the length. In this implementation method, the standard that proposes multiple data guard interval lengths is a beacon frame with multiple data guard interval lengths supported by the access device in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

In order to more clearly explain the technical solution in the embodiment of the present invention, the accompanying drawings necessary for explaining the embodiment will be briefly described below. Obviously, the accompanying drawings in the following description only show some embodiments of the present invention, and those skilled in the art will obtain other drawings from these attached drawings without any creative effort. Can be done.

It is a figure which shows the application scenario of the data communication method by this invention. It is a schematic flowchart of the data communication method by this invention. It is a schematic flowchart of another data communication method by this invention. It is a schematic flowchart of still another data communication method by this invention. It is a schematic flowchart of still another data communication method by this invention. It is a schematic block diagram of the element newly added by this invention. It is a schematic block diagram of another newly added element by this invention. A table of data GI lengths supported by APs in the HEW standard. Another table of data GI lengths supported by APs in the HEW standard. It is an instruction index value correspondence table by this invention. It is a schematic block diagram of the field newly added by this invention. It is a table for demonstrating the newly added field by this invention. It is a schematic block diagram of another newly added field by this invention. It is another table for explaining the newly added field by this invention. Yet another table of data GI lengths supported by APs in the HEW standard. It is a schematic block diagram of yet another newly added field by this invention. Yet another table for explaining the newly added fields according to the present invention. Yet another table for explaining the newly added fields according to the present invention. It is an encapsulation format of PPDU1 in the 802.11ac standard. It is an encapsulation format of PPDU2 according to the present invention. It is a table for demonstrating each field in PPDU2 by this invention. Another encapsulation format for PPDU 2 according to the present invention. It is a separate table for describing each field in PPDU 2 according to the present invention. Yet another PPDU2 encapsulation format according to the invention. Yet another table for describing each field in PPDU 2 according to the present invention. It is a figure which shows the broadcasting method of PPDU1 and PPDU2 by this invention. It is a figure which shows another broadcasting method of PPDU1 and PPDU2 by this invention. It is a schematic block diagram of the access device by this invention. It is a schematic block diagram of the encapsulation module by this invention. It is a schematic block diagram of the terminal by this invention. It is a schematic block diagram of another access device by this invention. It is a schematic block diagram of another terminal of this invention.

Hereinafter, the technical solution according to the embodiment of the present invention will be clearly described with reference to the accompanying drawings according to the embodiment of the present invention. Obviously, the embodiments described are only part, but not all, of the embodiments of the present invention. All other embodiments obtained by one of ordinary skill in the art based on the embodiments of the present invention without any creative effort shall fall within the scope of protection of the present invention.

The access device may be an access point (AP), also referred to as a wireless access point, hotspot, or the like. APs are access points that mobile users go through when entering a wired network, APs are primarily located in homes or buildings and parks, with typical coverage radii of tens to hundreds of meters. Of course, it may be deployed outdoors. An AP corresponds to a bridge connecting a wired network and a wireless network. The main function of the AP is to connect all wireless network clients and connect the wireless network to Ethernet®. Currently, the standard mainly used by APs is the IEEE (Institute of Electrical and Electronics Engineers) 802.11 family. Specifically, the AP may be a terminal device or a network device having a WiFi chip. Optionally, the AP may be a device that supports the 802.11ax standard, and optionally, the AP may be 802.11ac, 802.11n, 802.11g, 802.11b, and 802. It may be a device that supports a plurality of WLANs (wireless local area networks) such as 11a.

The terminal may be a wireless communication chip, a wireless sensor, or a wireless communication terminal. For example, the terminal may be a mobile phone that supports wireless fidelity (WiFi) communication, a tablet computer that supports WiFi communication, a set-top box that supports WiFi communication, or a computer that supports WiFi communication. Good. Optionally, the terminal may support the 802.11ax standard, and optionally, the terminal may be such as 802.11ac, 802.11n, 802.11g, 802.11b, and 802.11a. Multiple WLAN standards may be supported.

In the prior art, for example the 802.11ac standard, the data GI length used in the process of data communication between the AP and STA is 0.8us. The HEW standard proposes more options for data GI lengths, including data GI lengths such as 0.4us, 0.8us, 1.2us, 1.6us, 2.4us, 3.2us. Therefore, the fixed data GI length of the prior art cannot be adapted for data communication between AP and STA under the new HEW standard. As shown in Figure 1, if the AP supports HEW standard STA2 and STA3 and 802.11ac standard STA1, and a 0.8us data GI length is used between the AP and STA, STA1 And STA2 is within the coverage area of 0.8us, so STA1 and STA2 can perform data communication with the AP. However, since STA3 exceeds the coverage area of 0.8us, it cannot perform data communication with the AP.

Embodiments of the present invention may be applied to the application scenario of FIG. The AP broadcasts a beacon frame to all STAs, where the beacon frame carries the newly added field, which is used to represent multiple data GI lengths supported by the AP. However, when receiving a beacon frame broadcast by the AP, the terminal analyzes multiple data GI lengths supported by the AP and determines a data GI length that matches the data GI length supported by the terminal. This is to select as the data GI length used for data communication between the terminal and the AP. Therefore, in the embodiment of the present invention, data communication between the AP and the STA can be normally performed when there are a plurality of data GI lengths proposed in the HEW standard.

Referring to FIG. 2, FIG. 2 is a data communication method according to an embodiment of the present invention. As shown in FIG. 2, the data communication method of the present embodiment includes steps S100 to S101.

S100. The access device constructs a beacon frame, the beacon frame contains a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device.

In certain embodiments, the data GI lengths supported by the new generation standard solution HEW currently being studied by the standardization group are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}. The access device is a wireless access point (AP). In the present invention, in order for the AP to better indicate the data GI length information, newly added fields are referred to as "HE-enabled GI" fields and added to the beacon frame, and the newly added fields are supported by the AP. Used to represent multiple GI lengths. The "HE-enabled GI" is used to exchange the data GI lengths supported by each of the AP and STA between the AP and the STA. In the following, detailed description will be provided individually in aspects such as the position of the "HE-enabled GI" field and the format of the "HE-enabled GI" field.

The "HE-enabled GI" field can be placed at any position within the beacon frame. For example, the field may be placed on an existing element of the beacon frame or on a newly added element created within the beacon frame. In addition, the field may be placed in the SIG field of the presentation protocol data unit (PPDU) frame of the physical layer carrying the beacon frame. In the following, consider the case of creating a newly added element in order to place the "HE-compatible GI" field. The newly created element is called an HE ability element. In this case, the "HE-enabled GI" field may be arranged as follows.

In the first selective implementation, the "HE-enabled GI" field is placed directly on the "HE capability" element, and the "HE capability" information element describes the selective capability of the AP that supports the WLAN solution. Contains the fields used for. The "HE-enabled GI" field may be placed, for example, in the "HE capability" element and may be placed in the manner shown in FIG.

In the second selective implementation, the "HE-enabled GI" field is placed in the field of the "HE capability" element. As shown in FIG. 7, the "HE capability" element includes an "HE capability information" field, which is used to indicate the AP's capability information. The "HE-enabled GI" field may be placed in the "HE capability information" field above.

In the present invention, the newly added field, namely the "HE-enabled GI" field, indicates the data GI length supported by the AP, and in the new generation standard HEW solution, the bandwidth supported by the AP is 20MHz, 40MHz, 80MHz. , Or 160 MHz. As shown in Figure 8, there are multiple GI lengths at various bandwidths. The data GI length supported by the AP is N (N = 1, 2, 3, ..., 32) x 0.4 us. The "HE-enabled GI" field can be represented in multiple ways. Although some representations are used separately below as examples for illustration, it should be noted that the present specification is not limited to any particular representation.

In the first selective implementation, the newly added field contains an indicator value corresponding to each preset bandwidth, which the access device can use within the preset bandwidth. Represents the minimum data guard interval length for all supported data guard interval lengths, and preset bandwidths may include 20MHz, 40MHz, 80MHz, and 160MHz. For ease of explanation, a particular representation method randomly picks M data GI lengths from all data GI lengths supported by the various bandwidths shown in the table in Figure 8 as GI lengths supported by the AP. It may be a choice, which is shown in Figure 9. N is a serial number, and the value of N is {1, 2, ... .. .. , M}, m represents the bit amount of the indicating bit, and N corresponds to the value of the indicating bit on a one-to-one basis. Assuming that 6 data GI lengths are selected, M = 6, N = {1, 2
,. .. .. , 6}, m = 3, and the relationship between N and the indicator bit is as shown in FIG. For simplicity, assuming that the AP does not support some data GI lengths, a "-" indicates that the AP in the corresponding bandwidth does not support that GI length.

Assuming that the minimum data GI length supported by the AP is min_GI, the index value corresponding to min_GI is N, and each of the various bandwidths corresponds to one min_GI. FIG. 10 shows the min_GI supported by the AP in various bandwidths and the relationship between the min_GI and the serial number and the indicating bit obtained by FIG.

The indicated index value included in the "HE compatible GI" field refers to the index value corresponding to min_GI indicated by the "HE compatible GI" field in various bandwidths. The index value corresponding to min_GI indicated by the "HE-enabled GI" field in various bandwidths refers to the serial number corresponding to the min_GI supported by the AP in each bandwidth and carried by the field as "HE-enabled GI". .. For example, the data GI lengths supported in the 20MHz bandwidth are {0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}. Assuming that the min_GI supported in the 20MHz bandwidth is 0.8us, the indicator value of the 20MHz serial number is 2. Refer to 20MHz processing to process 40MHz, 80MHz, and 160MHz. Specifically, the indicator index value of the "HE-compatible GI" field in the beacon frame is represented in a binary coded format, that is, in the format of an indicator bit, and a specific representation format is shown in FIG. The “HE-enabled GI” field includes an indicator value for each preset bandwidth, and the indicator value GI_Idx is represented by bit information. A specific bit information representation is shown in FIG.

In the second selective implementation, the newly added field contains an indicator bit for each preset data guard interval length, which indicates whether the access device supports the preset data guard interval length. Used to indicate. In this implementation method, the influence of bandwidth is not considered, and M data GI lengths are selected as preset data GI lengths from the data GI lengths shown in FIG. For example, the preset data GI length is {0.4us, 0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}.

The HE-enabled GI field uses an indicator bit to indicate whether the AP supports preset data GI lengths. The "HE-enabled GI" field may use a single bit of indicator bit to indicate each data GI length in all preset data GI lengths, and each bit information bit indicates one data GI length. The representation of the "HE-enabled GI" field is shown in Figure 13, where one bit indicates one data GI length. Specific bit information indications are shown in FIG.

In a third selective implementation, the newly added field contains an indicator bit for each preset data guard interval length within each preset bandwidth, and the indicator bits are preset by the access device. Used to indicate whether preset data guard interval lengths within the bandwidth are supported. In this embodiment, as shown in FIG. 15, M data GI lengths are randomly selected from all the data GI lengths shown in FIG. 8 and are supported in various bandwidths as the data GI lengths supported by the AP. However, here M = 5. The "HE-enabled GI" field indicates the data GI length supported by each bandwidth means that the "HE-enabled GI" field uses a single-bit indicator bit to indicate the data GI length supported by the AP. That is, each bit separately indicates the data GI lengths supported by the various bandwidths, and the representation of the "HE-enabled GI" field is shown in Figure 16. Specific bit information is shown in FIGS. 17A and 17B.

S101. Allowing the terminal to perform data communication with the access device by selecting an available guard interval length from the beacon frame that matches the data guard interval length supported by the terminal and using the available guard interval length. The access device broadcasts the beacon frame.

In certain embodiments, the access device broadcasts the constructed beacon frame, and certain broadcasting methods may encapsulate the beacon frame in PPDU format for broadcasting. There may be multiple PPDU format encapsulation methods. For example, the beacon frame may be encapsulated in PPDU1 by the existing standard 802.11ac, or by the new generation standard HEW so that terminals supporting the new generation standard HEW can identify and analyze PPDU2. Another encapsulation method may be created to encapsulate the beacon frame in PPDU2, but see the description in Figure 3 for a specific creation method.

When terminal STA1 supporting the 802.11ac standard and terminal STA2 supporting the new generation standard HEW coexist within the broadcast range, the access device AP encapsulates both STA1 and STA2 so that they can access the network. Encapsulated PPDU1 and PPDU2 need to be broadcast. The broadcast method of PPDU1 may be to broadcast PPDU1 during a specific period preset by existing standards. A calculated field may be added to PPDU1 to broadcast PPDU2, but the calculated field may indicate the broadcast time of PPDU2 as it broadcasts PPDU2 at the time indicated by the calculated field.

After receiving the beacon frame broadcast by the AP and encapsulating it in PPDU1 format, STA1 accesses the network according to the existing 802.11ac standard. After detecting PPDU1 and / or PPDU2, STA2 analyzes the beacon frame, analyzes each capability element of the beacon frame, analyzes the "HE-enabled GI" field of the capability element, and determines the data GI length supported by the AP. get. STA2 obtains the available data GI length used for communication with the AP by the data GI length supported by STA2, but the available data GI length matches the data GI length supported by STA2. And refer to the data GI length in the data GI length supported by the AP. For example, the data GI lengths supported by STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, and the data GI lengths supported by AP are {0.4us, 0.8us, 1.6us. , 2.0us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, in this case {0.8us, 1.6us, 2.4us, 3.2us} is the available data GI length. Subsequently, STA2 performs data communication with the AP by using a selectable data GI length. Specifically, STA2 selects the data GI length from the available GI lengths according to the channel conditions. Data communication may be performed with the AP.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

Referring to FIG. 3, FIG. 3 is another data communication method according to an embodiment of the present invention. As shown in FIG. 3, the data communication method of the present embodiment includes steps S200 to S202.

S200. The access device constructs a beacon frame, the beacon frame contains a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device.

S201. The access device encapsulates the beacon frame separately into a first standard protocol data unit and a second standard protocol data unit.

In a particular embodiment, consider the case where an STA supporting the first standard and an STA supporting the second standard coexist on the network. For example, STA1 supports the first standard and STA2 supports the second standard. The first or second standard above may be a different WIFI solution, a solution to an existing WIFI standard such as 802.11ac, or a new generation standard solution HEW currently being studied by the standardization group. It may be another similar WIFI solution.

When encapsulating the beacon frame in PPDU format, the access device AP must encapsulate the beacon frame in two PPDU formats, the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2. PPDU1 is obtained by encapsulation according to the first standard and PPDU2 is obtained by encapsulation according to the second standard. The specific encapsulation method will be described in detail below, but specifically includes steps S20 to S22.

S20. The access device obtains the maximum data guard interval length from the data guard interval length supported by the access device in the first standard, and determines the maximum data guard interval length as the first alternative data guard interval length.

In certain embodiments, the AP separately supports a set of data GI lengths in the first standard and the second standard. The first alternative data GI length refers to the maximum data GI length in a set of GIs supported by the AP in the first standard. For example, if the data GI length supported by the first standard AP is {0.4us, 0.8us}, the first alternative data GI length refers to the data GI length of 0.8us.

S21. The access device obtains the maximum data guard interval length from the data guard interval length supported by the access device in the second standard, and determines the maximum data guard interval length as the second alternative data guard interval length.

In certain embodiments, the AP also supports a set of data GI lengths in the second standard, and the second alternative data guard interval length is the maximum data in the set of GIs supported by the AP in the second standard. Refer to the GI length. For example, if the set of data GI lengths supported by the AP in the second standard is {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}, then the second alternative data GI length is , 3.2 Refer to the data length of us.

If there is a wider variety of STAs in the network that support different standards, that is, if there are multiple types of STAs, then different types of STAs support different standards, but STAs that support different standards. It should be noted that there may be compatibility between them. However, STA has only upward compatibility instead of backward compatibility. For example, a STA that supports HEW is compatible with a STA that supports the 802.11ac standard, but a STA that supports the 802.11ac standard is not compatible with a STA that supports HEW. For example, if there are multiple types of STAs on the network, the number of different standards supported by the various STAs in the network is 3, 4, or more, and the alternate data GI length is determined accordingly. In this case, the number of alternative data GI lengths may be correspondingly 3, 4, or more. For the sake of simplicity, assuming that the two STAs in the network support the first standard (such as the 802.11ac standard solution) and the second standard (such as the current HEW standard solution), respectively: The contents of the present invention will be described in the above, but the alternative data GI lengths are GI1 and GI2.

S22. The access device separately encapsulates the beacon frame into the first standard protocol data unit and the second standard protocol data unit by the first alternative data guard interval length and the second alternative data guard interval length.

In certain embodiments, the access device provides a beacon frame with a first alternative data guard interval length GI1 and a second alternative data guard interval length GI2, a first standard protocol data unit PPDU1 and a second standard protocol data. Encapsulated in unit PPDU2, but constructed PPDU1 and PPDU2 must comply with the PPDU format in their respective standards. The formats of PPDU1 and PPDU2 will be described separately below.

As shown in FIG. 18, optionally, the PPDU1 format includes preamble and bearer data, the bearer data includes beacon frames, and the preamble GI length and data GI length in the PPDU1 format are GI1, respectively. The purpose of the AP sending PPDU1 is to make STA1 network discoverable, which supports the first standard. The first standard may be the 802.11ac standard.

Optionally, the second standard may be the HEW standard. With reference to the HEW standard, the PPDU2 format has multiple design methods, but is not limited to this. The design of three selective PPDU2 formats is shown below.

As shown in FIG. 19, in the first selective implementation, the PPDU2 contains a legacy preamble, a high efficiency radio local area network preamble, and bearer data, a combination of L-STF, L-LTF, and L-SIG. Is called a legacy preamble, and a combination of HE-SIG, HE-STF, and another possible field is called a HEW preamble. The GI length of the legacy preamble, the GI length of the HEW preamble, and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. Note that STA2 can also detect PPDU1 and process PPDU1. A description of all the fields in FIG. 19 is shown in FIG.

As shown in Figure 21, in the second selective implementation, the PPDU2 format includes a legacy preamble, a high efficiency radio local area network preamble, and bearer data, the legacy preamble has a GI length of GI1 and a HEW preamble. The GI length of the bearer data and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. The length of the PPDU2 format legacy preamble in the first selective implementation, obtained from Figure 20, is 80us. The length of the PPDU2 format legacy preamble in the second selective implementation, obtained from FIG. 22, is 20us. If the remaining field lengths are the same, the second selective practice reduces the transmission overhead by 60us. A description of all the fields in FIG. 21 is shown in FIG.

In a third selective implementation, the PPDU2 format is shown in Figure 23, where PPDU2 contains highly efficient radio local area network preambles and bearer data. A description of all the fields in FIG. 23 is shown in FIG. The GI length of the HEW preamble and the GI length of the bearer data are GI2 respectively, and the purpose of the AP to send PPDU2 is to make STA2 network discoverable, which supports the second standard. Compared to the PPDU format in the first selective implementation, the PPDU format in the third selective implementation removes the legacy preamble. Therefore, if the remaining field lengths are the same, the transmit overhead is reduced by 80us compared to the PPDU format in the first selective implementation.

S202. The access device broadcasts a beacon frame encapsulated in a first standard protocol data unit and a beacon frame encapsulated in a second standard protocol data unit.

In certain embodiments, the access device broadcasts a beacon frame encapsulated in PPDU1 and a beacon frame encapsulated in PPDU2, whereas a particular broadcast method broadcasts PPDU1 during a preset period of time. It may be to broadcast PPDU2 at the broadcast time of. However, it is necessary to add a calculated field indicating the transmission time of PPDU2 to PPDU1.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

Referring to FIG. 4, FIG. 4 is another data communication method according to an embodiment of the present invention. As shown in FIG. 4, the data communication method of the present embodiment includes steps S300 to S304.

S300. The access device constructs a beacon frame, the beacon frame contains a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device.

S301. The access device encapsulates the beacon frame separately into a first standard protocol data unit and a second standard protocol data unit.

S302. The access device adds a calculated field used to indicate the transmission time of the second standard protocol data unit to the first standard protocol data unit.

In certain embodiments, the AP transmits the constructed PPDU1 and PPDU2. Assuming that PPDU1 is constructed by the 802.11ac standard, the transmission period of PPDU1 specified by the 802.11ac standard is T1, and the transmission time of PPDU2 by the AP may be specified randomly, and the AP is For example, PPDU1 and PPDU2 are transmitted alternately. A calculated field may be added to PPDU1 for display, or a calculated field may be added to PPDU2 for display. The calculated field is used to indicate the transmission time of PPDU2. The calculated field may indicate the transmission time of PPDU2 in a plurality of display methods, but only two methods are described below.

In the first selective implementation, the HE calculated field uses only one bit to indicate whether the next m * T (eg, m = 2/3) period has PPDU2, where , T is the preset period for broadcasting PPDU1. That is, if the value of the HE calculated field is 1, it means that the next m * T period has PPDU2, and if the value of the HE calculated field is 0, the next m * T period does not have PPDU2. Show that. As shown in FIG. 25, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 0, it does not have PPDU2 during the next m * T period.

In the second selective implementation, the HE calculated field has two or more bits, represented as x bits. The HE calculated field may be used to indicate whether the next (n + m * T) period (eg, m = 2/3, where n is a natural number indicated by x bits) has PPDU2. That is, when the value of the HE operation field is n, it indicates that the next (n + m * T) period has PPDU2. As shown in FIG. 26, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 2, the next two m * T periods have PPDU2.

S303. The access device broadcasts a first standard protocol data unit containing calculated fields during the preset period.

In certain embodiments, the access device broadcasts a PPDU 1 containing a calculated field during a particular preset period. PPDU1 may be encapsulated by the 802.11ac standard, and therefore PPDU1 may be broadcast by a period preset in the 802.11ac standard.

S304. The access device broadcasts a second standard protocol data unit at the transmission time indicated by the calculated field.

In certain embodiments, the access device broadcasts PPDU2 at the transmit time indicated by the calculated field, as shown in FIG. 25 or FIG. Upon receiving PPDU1, the terminal may know the transmission time of PPPDU2 from the calculated field, or may receive PPDU2 at the known transmission time.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

Referring to FIG. 5, FIG. 5 is another data communication method according to an embodiment of the present invention. As shown in FIG. 5, the data communication method of the present embodiment includes steps S400 to S402.

S400. The terminal acquires the beacon frame broadcast by the access device, the beacon frame contains a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device.

In certain embodiments, the terminal STA acquires the beacon frame broadcast by the access device, but the beacon frame may be a beacon frame, which includes a newly added field and is newly added. The field represents multiple data GI lengths supported by the access device. The processing procedure of STA corresponds to the processing procedure of the access device AP described above. The AP side encapsulates the beacon frame in the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2, but the first standard may be the 802.11ac standard and the second standard is It may be a HEW standard. In this embodiment, if STA1 supporting the first standard and STA2 supporting the second standard are present on the network, STA1 can perform normal detection processing only in PPDU1. The detection processing method is not described in detail here, but refer to the 802.11ac standard solution. The STA processing procedure described here refers to the above STA2 processing procedure.

The AP transmits PPDU1 during a preset period, which contains a calculated field used to indicate the transmission time of PPDU2, which indicates the transmission time of PPDU2. Specifically, there are three selective implementations of the method used by the STA to capture beacon frames broadcast by the AP.

In the first selective implementation, when the STA gets the PPDU1 broadcast by the AP, the STA processes the PPDU1 and parses the beacon frame from the PPDU1 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU1. For example, if the preamble of PPDU1 is GI1, the STA sets the preamble for subsequent data communication to GI1.

In the second selective implementation, when the STA gets the PPDU2 broadcast by the AP, the STA processes the PPDU2 and parses the beacon frame from the PPDU2 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

In the third selective implementation method, when the STA receives PPDU1, the STA obtains the transmission time of the next PPDU 2 from PPDU 1 by analyzing the "HE operation" field. For example, if the "HE operation" uses bits to indicate whether the next period has PPDU2, then if the "HE operation" field indicates 0, then the STA must detect PPDU2 in the next period. If there is, or if the "HE Calculator" field shows 1, it indicates that the STA does not need to detect PPDU2 during the next period. STA analyzes the beacon frame from the detected PPDU2. In addition, the STA determines the preamble length for subsequent data communication between the STA and AP by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

S401. The terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from a plurality of data guard interval lengths supported by the access device.

In a particular embodiment, the terminal STA analyzes the beacon frame after acquiring the beacon frame. The specific analysis method is that the STA detects all the capability elements of the beacon frame and analyzes the "HE-enabled GI" field to obtain the data GI length supported by the AP, and the STA supports the STA. It may be to set the available GI length based on the data GI length and the acquired data GI length supported by the AP. For example, if the data GI length indicated by the information about the "HE compatible GI" field is {0.8us, 1.6us, 2.4us}, the data GI length supported by the AP is {0.8us, 1.6us. , 2.4us}. The GI lengths supported by the STA itself are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us}, in which case {0.8us, 1.6us} is the available data GI length. In the subsequent communication between the STA and AP, the data GI length is selected from the available data GI lengths according to the channel state to construct a PPDU.

S402. The terminal performs data communication with the access device by using the available guard interval length.

In certain embodiments, after obtaining the available data GI length, the STA may perform data communication with the AP by using the available data GI length. Specifically, in the subsequent communication between the STA and the AP, the data GI length is selected from the available data GI lengths according to the channel state to construct the PPDU.

In addition, the STA generates an association request frame based on the available data GI length and sends the association request frame to the AP. After receiving the association request frame, the AP analyzes the association request frame and returns the association response frame to the STA if the STA is allowed access to the network. After receiving the association response frame, the STA analyzes the association response frame. In this case, the STA may establish an association with the AP, after which the AP and STA may perform data communication for data transmission.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

With reference to FIG. 27, FIG. 27 is a schematic structural diagram of the access device according to the present invention. As shown in FIG. 27, the access device according to the present embodiment includes a construction module 100, an encapsulation module 101, a processing module 102, and a transceiver module 103.

Construction module 100 is configured to build a beacon frame, where the beacon frame contains newly added fields, which represent multiple data guard interval lengths supported by the access device. ..

In certain embodiments, the data GI lengths supported by the new generation standard solution HEW currently being studied by the standardization group are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}. The access device is a wireless access point (AP). In the present invention, in order for the AP to better indicate the data GI length information, the construction module 100 adds the newly added field to the beacon frame as a "HE-compatible GI" field, and the newly added field. Is used to represent multiple GI lengths supported by the AP. The "HE-enabled GI" field is used to exchange the data GI lengths supported by the AP and STA, respectively, between the AP and the STA. In the following, detailed description will be provided individually in aspects such as the position of the "HE-enabled GI" field and the format of the "HE-enabled GI" field.

The "HE-enabled GI" field can be placed at any position within the beacon frame. For example, the field may be placed on an existing element of the beacon frame or on a newly added element created within the beacon frame. In addition, the field may be placed in the SIG field of the presentation protocol data unit (PPDU) frame of the physical layer carrying the beacon frame. In the following, consider the case of creating a newly added element in order to place the "HE-compatible GI" field. The newly created element is called an HE ability element. In this case, the "HE-enabled GI" field may be arranged as follows.

In the first selective implementation, the "HE-enabled GI" field is placed directly on the "HE capability" element, and the "HE capability" information element describes the selective capability of the AP that supports the WLAN solution. Contains the fields used for. The "HE-enabled GI" field may be placed, for example, in the "HE capability" element and may be placed in the manner shown in FIG.

In the second selective implementation, the "HE-enabled GI" field is placed in the field of the "HE capability" element. As shown in FIG. 7, the "HE capability" element includes an "HE capability information" field, which is used to indicate the AP's capability information. The "HE-enabled GI" field may be placed in the "HE capability information" field above.

In the present invention, the newly added field, namely the "HE-enabled GI" field, indicates the data GI length supported by the AP, and in the new generation standard HEW solution, the bandwidth supported by the AP is 20MHz, 40MHz, 80MHz. , Or 160 MHz. As shown in Figure 8, there are multiple GI lengths at various bandwidths. The data GI length supported by the AP is N (N = 1, 2, 3, ..., 32) x 0.4 us. The "HE-enabled GI" field can be represented in multiple ways. Although some representations are used separately below as examples for illustration, it should be noted that the present specification is not limited to any particular representation.

In the first selective implementation, the newly added field contains an indicator value corresponding to each preset bandwidth, which the access device can use within the preset bandwidth. Represents the minimum data guard interval length for all supported data guard interval lengths, and preset bandwidths may include 20MHz, 40MHz, 80MHz, and 160MHz. For ease of explanation, a particular representation method randomly picks M data GI lengths from all data GI lengths supported by the various bandwidths shown in the table in Figure 8 as GI lengths supported by the AP. It may be a choice, which is shown in Figure 9. N is a serial number, and the value of N is {1, 2, ... .. .. , M}, m represents the bit amount of the indicating bit, and N corresponds to the value of the indicating bit on a one-to-one basis. Assuming that 6 data GI lengths are selected, M = 6, N = {1, 2, ... .. .. , 6}, m = 3, and the relationship between N and the indicator bit is as shown in FIG. For simplicity, assuming that the AP does not support some data GI lengths, a "-" indicates that the APs in the corresponding bandwidth do not support that GI length.

Assuming that the minimum data GI length supported by the AP is min_GI, the index value corresponding to min_GI is N, and each of the various bandwidths corresponds to one min_GI. FIG. 10 shows the min_GI supported by the AP in various bandwidths and the relationship between the min_GI and the serial number and the indicating bit obtained by FIG.

The indicated index value included in the "HE compatible GI" field refers to the index value corresponding to min_GI indicated by the "HE compatible GI" field in various bandwidths. The index value corresponding to min_GI indicated by the "HE-enabled GI" field in various bandwidths refers to the serial number corresponding to min_GI supported in each bandwidth and carried by the "HE-enabled GI" field. For example, the data GI lengths supported in the 20MHz bandwidth are {0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}. Assuming that the min_GI supported in the 20MHz bandwidth is 0.8us, the indicator value of the 20MHz serial number is 2. Refer to 20MHz processing to process 40MHz, 80MHz, and 160MHz. Specifically, in the beacon frame, "
The indicator value of the "HE-enabled GI" field is expressed in binary coded form, that is, in the form of indicator bits, and the specific representation format is shown in FIG. 11, where the "HE-enabled GI" field is each The indicator index value GI_Idx, which includes the indicator indicator value of the preset bandwidth, is represented by bit information. A specific bit information representation is shown in FIG.

In the second selective implementation, the newly added field contains an indicator bit for each preset data guard interval length, which indicates whether the access device supports the preset data guard interval length. Used to indicate. In this implementation method, the influence of bandwidth is not considered, and M data GI lengths are selected as preset data GI lengths from the data GI lengths shown in FIG. For example, the preset data GI length is {0.4us, 0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}.

The HE-enabled GI field uses an indicator bit to indicate whether the AP supports preset data GI lengths. The "HE-enabled GI" field may use a single bit of indicator bit to indicate each data GI length in all preset data GI lengths, and each bit information bit indicates one data GI length. The representation of the "HE-enabled GI" field is shown in Figure 13, where one bit indicates one data GI length. Specific bit information indications are shown in FIG.

In a third selective implementation, the newly added field contains an indicator bit for each preset data guard interval length within each preset bandwidth, and the indicator bits are preset by the access device. Used to indicate whether preset data guard interval lengths within the bandwidth are supported. In this embodiment, as shown in FIG. 15, M data GI lengths are randomly selected from all the data GI lengths shown in FIG. 8 and are supported in various bandwidths as the data GI lengths supported by the AP. However, here M = 5. The "HE-enabled GI" field indicates the data GI length supported by each bandwidth means that the "HE-enabled GI" field uses a single-bit indicator bit to indicate the data GI length supported by the AP. That is, each bit separately indicates the data GI lengths supported by the various bandwidths, and the representation of the "HE-enabled GI" field is shown in Figure 16. Specific bit information is shown in FIGS. 17A and 17B.

The transceiver module 103 is configured to broadcast a beacon frame and perform data communication with a terminal.

In certain embodiments, the transceiver module 103 of the access device broadcasts the constructed beacon frame, and the particular broadcasting method may be to encapsulate the beacon frame in a PPDU format for broadcasting. There may be multiple PPDU format encapsulation methods. For example, the beacon frame may be encapsulated in PPDU1 by the existing standard 802.11ac, or by the new generation standard HEW so that terminals supporting the new generation standard HEW can identify and analyze PPDU2. Another encapsulation method may be created to encapsulate the beacon frame in PPDU2, but for specific creation methods, see the description of subsequent embodiments.

When terminal STA1 supporting the 802.11ac standard and terminal STA2 supporting the new generation standard HEW coexist within the broadcast range, the access device AP encapsulates both STA1 and STA2 so that they can access the network. Encapsulated PPDU1 and PPDU2 need to be broadcast. The broadcast method of PPDU1 may be to broadcast PPDU1 during a specific period preset by existing standards. A calculated field may be added to PPDU1 to broadcast PPDU2, but the calculated field may indicate the broadcast time of PPDU2 as it broadcasts PPDU2 at the time indicated by the calculated field.

After receiving the beacon frame broadcast by the AP and encapsulating it in PPDU1 format, STA1 accesses the network according to the existing 802.11ac standard. After detecting PPDU1 and / or PPDU2, STA2 analyzes the beacon frame, analyzes each capability element of the beacon frame, analyzes the "HE-enabled GI" field of the capability element, and determines the data GI length supported by the AP. get. STA2 obtains the available data GI length used for communication with the AP by the data GI length supported by STA2, but the available data GI length matches the data GI length supported by STA2. And refer to the data GI length in the data GI length supported by the AP. For example, the data GI lengths supported by STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, and the data GI lengths supported by AP are {0.4us, 0.8us, 1.6us. , 2.0us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, in this case {0.8us, 1.6us, 2.4us, 3.2us} is the available data GI length. Subsequently, STA2 performs data communication with the AP by using a selectable data GI length. Specifically, STA2 selects the data GI length from the available GI lengths according to the channel conditions. Data communication may be performed with the AP.

Optionally, the access device may further include an encapsulation module 101.

The encapsulation module 101 is configured to separately encapsulate the beacon frame into a first standard protocol data unit and a second standard protocol data unit.

In a particular embodiment, consider the case where an STA supporting the first standard and an STA supporting the second standard coexist on the network. For example, STA1 supports the first standard and STA2 supports the second standard. The first or second standard above may be a different WIFI solution, an existing WIFI standard solution such as 802.11ac, or a new generation standard solution HEW currently under consideration by the standardization group. It may be, or it may be another similar WIFI solution.

When encapsulating the beacon frame in PPDU format, the access device AP encapsulation module 101 encapsulates the beacon frame in two PPDU formats, the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2. PPDU1 is obtained by encapsulation according to the first standard and PPDU2 is obtained by encapsulation according to the second standard. See the description in Figure 28 for specific encapsulation methods.

The transceiver module 103 is specifically configured to broadcast a beacon frame encapsulated in a first standard protocol data unit and a beacon frame encapsulated in a second standard protocol data unit.

In certain embodiments, the access device transceiver module 103 broadcasts a beacon frame encapsulated in PPDU1 and a beacon frame encapsulated in PPDU2, whereas a particular broadcast method broadcasts PPDU1 during a preset period of time. It may be broadcast and broadcast PPDU2 at a specific broadcast time. However, it is necessary to add a calculated field indicating the transmission time of PPDU2 to PPDU1.

Optionally, the access device may further include a processing module 102.

The processing module 102 is configured to add an arithmetic field used to indicate the transmission time of the second standard protocol data unit to the first standard protocol data unit.

In certain embodiments, the AP transmits the constructed PPDU1 and PPDU2. Assuming that PPDU1 is constructed by the 802.11ac standard, the transmission period of PPDU1 specified by the 802.11ac standard is T1, and the transmission time of PPDU2 by the AP may be specified randomly, and the AP is For example, PPDU1 and PPDU2 are transmitted alternately. The processing module 102 may add a calculated field to PPDU1 for display or may add a calculated field to PPDU2 for display. The calculated field is used to indicate the transmission time of PPDU2. The calculated field may indicate the transmission time of PPDU2 in a plurality of display methods, but only two methods are described below.

In the first selective implementation, the HE calculated field uses only one bit to indicate whether the next m * T (eg, m = 2/3) period has PPDU2, where , T is the preset period for broadcasting PPDU1. That is, if the value of the HE calculated field is 1, it means that the next m * T period has PPDU2, and if the value of the HE calculated field is 0, the next m * T period does not have PPDU2. Show that. As shown in FIG. 25, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 0, it does not have PPDU2 during the next m * T period.

In the second selective implementation, the HE calculated field has two or more bits, represented as x bits. The HE calculated field may be used to indicate whether the next (n + m * T) period (eg, m = 2/3, where n is a natural number indicated by x bits) has PPDU2. That is, when the value of the HE operation field is n, it indicates that the next (n + m * T) period has PPDU2. As shown in FIG. 26, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 2, the next two m * T periods have PPDU2.

The transceiver module 103 is specifically configured to broadcast a first standard protocol data unit containing arithmetic fields for a preset period of time.

In certain embodiments, the transceiver module 103 of the access device broadcasts a PPDU 1 containing a calculated field during a particular preset period. PPDU1 may be encapsulated by the 802.11ac standard, and therefore PPDU1 may be broadcast by a period preset in the 802.11ac standard.

The transceiver module 103 is further configured to broadcast a second standard protocol data unit at the transmit time indicated by the calculated field.

In certain embodiments, the transceiver module 103 of the access device broadcasts PPDU2 at the transmit time indicated by the calculated field, as shown in FIG. 25 or 26. Upon receiving PPDU1, the terminal may know the transmission time of PPPDU2 from the calculated field, or may receive PPDU2 at the known transmission time.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

With reference to FIG. 28, FIG. 28 is a schematic structural diagram of the encapsulation module according to the present invention. As shown in FIG. 28, the encapsulation module of the present embodiment includes a first acquisition unit 1030, a second acquisition unit 1031, and an encapsulation unit 1032.

The first acquisition unit 1030 should acquire the maximum data guard interval length in the data guard interval length supported by the first standard access device and determine the maximum data guard interval length as the first alternative data guard interval length. It is composed of.

In certain embodiments, the AP separately supports a set of data GI lengths in the first standard and the second standard. The first alternative data GI length refers to the maximum data GI length in a set of GIs supported by the AP in the first standard. For example, if the data GI length supported by the first standard AP is {0.4us, 0.8us}, the first alternative data GI length refers to the data GI length of 0.8us.

The second acquisition unit 1031 should acquire the maximum data guard interval length in the data guard interval length supported by the second standard access device and determine the maximum data guard interval length as the second alternative data guard interval length. It is composed of.

In certain embodiments, the AP also supports a set of data GI lengths in the second standard, and the second alternative data guard interval length is the maximum data in the set of GIs supported by the AP in the second standard. Refer to the GI length. For example, if the set of data GI lengths supported by the AP in the second standard is {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}, then the second alternative data GI length is , 3.2 Refer to the data length of us.

If there is a wider variety of STAs in the network that support different standards, that is, if there are multiple types of STAs, then different types of STAs support different standards, but STAs that support different standards. It should be noted that there may be compatibility between them. However, STA has only upward compatibility instead of backward compatibility. For example, a STA that supports HEW is compatible with a STA that supports the 802.11ac standard, but a STA that supports the 802.11ac standard is not compatible with a STA that supports HEW. For example, if there are multiple types of STAs on the network, the number of different standards supported by the various STAs in the network is 3, 4, or more, and the alternate data GI length is determined accordingly. In this case, the number of alternative data GI lengths may be correspondingly 3, 4, or more. For the sake of simplicity, assuming that the two STAs in the network support the first standard (such as the 802.11ac standard solution) and the second standard (such as the current HEW standard solution), respectively: The contents of the present invention will be described in the above, but the alternative data GI lengths are GI1 and GI2.

The encapsulation unit 1032 separately encapsulates the beacon frame into the first standard protocol data unit and the second standard protocol data unit by the first alternative data guard interval length and the second alternative data guard interval length. It is configured as follows.

In certain embodiments, the access device encapsulation unit 1032 provides a beacon frame with a first alternative data guard interval length GI1 and a second alternative data guard interval length GI2, a first standard protocol data unit PPDU1 and a first. Encapsulated in two standard protocol data units, PPDU2, but the constructed PPDU1 and PPDU2 must comply with the PPDU format in their respective standards. The formats of PPDU1 and PPDU2 will be described separately below.

As shown in FIG. 18, optionally, the PPDU1 format includes preamble and bearer data, the bearer data includes beacon frames, and the preamble GI length and data GI length in the PPDU1 format are GI1, respectively. The purpose of the AP sending PPDU1 is to make STA1 network discoverable, which supports the first standard. The first standard may be the 802.11ac standard.

Optionally, the second standard may be the HEW standard. With reference to the HEW standard, the PPDU2 format has multiple design methods, but is not limited to this. The design of three selective PPDU2 formats is shown below.

As shown in FIG. 19, in the first selective implementation, the PPDU2 contains a legacy preamble, a high efficiency radio local area network preamble, and bearer data, a combination of L-STF, L-LTF, and L-SIG. Is called a legacy preamble, and a combination of HE-SIG, HE-STF, and another possible field is called a HEW preamble. The GI length of the legacy preamble, the GI length of the HEW preamble, and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. Note that STA2 can also detect PPDU1 and process PPDU1. A description of all the fields in FIG. 19 is shown in FIG.

As shown in Figure 21, in the second selective implementation, the PPDU2 format includes a legacy preamble, a high efficiency radio local area network preamble, and bearer data, the legacy preamble has a GI length of GI1 and a HEW preamble. The GI length of the bearer data and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. The length of the PPDU2 format legacy preamble in the first selective implementation, obtained from Figure 20, is 80us. The length of the PPDU2 format legacy preamble in the second selective implementation, obtained from FIG. 22, is 20us. If the remaining field lengths are the same, the second selective practice reduces the transmission overhead by 60us. A description of all the fields in FIG. 21 is shown in FIG.

In a third selective implementation, the PPDU2 format is shown in Figure 23, where PPDU2 contains highly efficient radio local area network preambles and bearer data. A description of all the fields in FIG. 23 is shown in FIG. The GI length of the HEW preamble and the GI length of the bearer data are GI2 respectively, and the purpose of the AP to send PPDU2 is to make STA2 network discoverable, which supports the second standard. Compared to the PPDU format in the first selective implementation, the PPDU format in the third selective implementation removes the legacy preamble. Therefore, if the remaining field lengths are the same, the transmit overhead is reduced by 80us compared to the PPDU format in the first selective implementation.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

With reference to FIG. 29, FIG. 29 is a schematic configuration diagram of a terminal according to an embodiment of the present invention. As shown in FIG. 29, the terminal in this embodiment of the present invention includes a transceiver module 200 and a selection module 201.

The transceiver module 200 is configured to acquire a beacon frame broadcast by the access device, where the beacon frame contains a newly added field and the newly added field contains multiple data supported by the access device. Represents the guard interval length.

In certain embodiments, the transceiver module 200 of the terminal STA acquires a beacon frame broadcast by the access device, but the beacon frame may be a beacon frame, which includes a newly added field and is new. The fields added to represent the multiple data GI lengths supported by the access device. The processing procedure of STA corresponds to the processing procedure of the access device AP described above. The AP side encapsulates the beacon frame in the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2, but the first standard may be the 802.11ac standard and the second standard is It may be a HEW standard. In this embodiment, if STA1 supporting the first standard and STA2 supporting the second standard are present on the network, STA1 can perform normal detection processing only in PPDU1. The detection processing method is not described in detail here, but refer to the 802.11ac standard solution. The STA processing procedure described here refers to the above STA2 processing procedure.

The AP transmits PPDU1 during a preset period, which contains a calculated field used to indicate the transmission time of PPDU2, which indicates the transmission time of PPDU2. Specifically, there are three selective implementations of the method used by the STA to capture beacon frames broadcast by the AP.

Optionally, the transceiver module 200 is specifically configured to acquire a first standard protocol data unit broadcast by the access device and analyze beacon frames from the first standard protocol data unit.

In the first selective implementation, when the STA gets the PPDU1 broadcast by the AP, the STA processes the PPDU1 and parses the beacon frame from the PPDU1 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU1. For example, if the preamble of PPDU1 is GI1, the STA sets the preamble for subsequent data communication to GI1.

Optionally, the transceiver module 200 is specifically configured to acquire a second standard protocol data unit broadcast by the access device and analyze the beacon frame from the second standard protocol data unit.

In the second selective implementation, when the STA gets the PPDU2 broadcast by the AP, the STA processes the PPDU2 and parses the beacon frame from the PPDU2 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

Optionally, the transceiver module 200 obtains the first standard protocol data unit broadcast by the access device and determines the transmission time of the second standard protocol data unit from the arithmetic fields in the first standard protocol data unit. Then, the second standard protocol data unit is acquired according to the transmission time, and the beacon frame is analyzed from the second standard protocol data unit.

In the third selective implementation method, when the STA receives PPDU1, the STA obtains the transmission time of the next PPDU 2 from PPDU 1 by analyzing the "HE operation" field. For example, if the "HE operation" uses bits to indicate whether the next period has PPDU2, then if the "HE operation" field indicates 0, then the STA must detect PPDU2 in the next period. If there is, or if the "HE Calculator" field shows 1, it indicates that the STA does not need to detect PPDU2 during the next period. STA analyzes the beacon frame from the detected PPDU2. In addition, the STA determines the preamble length for subsequent data communication between the STA and AP by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

The selection module 201 is configured to select an available guard interval length that matches the data guard interval length supported by the terminal from a plurality of data guard interval lengths supported by the access device.

In a particular embodiment, the terminal STA analyzes the beacon frame after acquiring the beacon frame. The specific analysis method is that the STA detects all capability elements of the beacon frame and analyzes the "HE-enabled GI" field to obtain the data GI length supported by the AP, and the STA selection module 201, It may be possible to set the available GI length based on the data GI length supported by the STA and the acquired data GI length supported by the AP. For example, if the data GI length indicated by the information about the "HE-enabled GI" field is {0.8us, 1.6us, 2.4us}, the data GI length supported by the AP is {0.8us, 1. 6us, 2.4us}. The GI lengths supported by the STA itself are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us}, in which case {0.8us, 1.6us} is the available data GI length. In the subsequent communication between the STA and AP, the data GI length is selected from the available data GI lengths according to the channel state to construct a PPDU.

The transceiver module 200 is further configured to perform data communication with the access device using the available guard interval length.

In certain embodiments, after the STA has acquired the available data GI length, the transceiver module 200 may perform data communication with the AP by using the available data GI length. Specifically, in the subsequent communication between the STA and the AP, the data GI length is selected from the available data GI lengths according to the channel state to construct the PPDU.

In addition, the STA generates an association request frame based on the available data GI length and sends the association request frame to the AP. After receiving the association request frame, the AP analyzes the association request frame and returns the association response frame to the STA if the STA is allowed access to the network. After receiving the association response frame, the STA analyzes the association response frame. In this case, the STA may establish an association with the AP, after which the AP and STA may perform data communication for data transmission.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

With reference to FIG. 30, FIG. 30 is a schematic configuration diagram of another access device according to the present invention. The access device 30 of FIG. 30 may be configured to implement all the steps and methods in the embodiment of the above method. In the embodiment of FIG. 30, the access device 30 includes a processor 300, a transceiver 301, a memory 302, an antenna 303, and a bus 304. The processor 300 controls the operation of the access device 30, but can also be configured to process the signal. Memory 302 may include read-only memory and random access memory to provide instructions and data for processor 300. The transceiver 301 may be connected to the antenna 303. All components of access device 30 are connected together by using bus system 304, which bus system 304 further includes a power bus, a control bus, and a status signal bus in addition to the data bus. However, for the sake of clarity, the figure shows various buses as the bus system 304. The access device 30 may be the AP shown in FIG. All components will be described in detail below.

The processor is configured to build a beacon frame, which contains a newly added field, which represents the multiple data guard interval lengths supported by the access device.

The transceiver is configured to broadcast beacon frames and perform data communication with terminals.

Optionally, the data GI lengths supported by the new generation standard solution HEW currently being studied by the standardization group are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us} and access. The device is a wireless access point (AP). In the present invention, in order for the AP to better indicate the data GI length information, newly added fields are referred to as "HE-enabled GI" fields and added to the beacon frame, and the newly added fields are supported by the AP. Used to represent multiple GI lengths. The "HE-enabled GI" field is used to exchange the data GI lengths supported by the AP and STA, respectively, between the AP and the STA. In the following, detailed description will be provided individually in aspects such as the position of the "HE-enabled GI" field and the format of the "HE-enabled GI" field.

The "HE-enabled GI" field can be placed at any position within the beacon frame. For example, the field may be placed on an existing element of the beacon frame or on a newly added element created within the beacon frame. In addition, the field may be placed in the SIG field of the presentation protocol data unit (PPDU) frame of the physical layer carrying the beacon frame. In the following, consider the case of creating a newly added element in order to place the "HE-compatible GI" field. The newly created element is called an HE ability element. In this case, the "HE-enabled GI" field may be arranged as follows.

In the first selective implementation, the "HE-enabled GI" field is placed directly on the "HE capability" element, and the "HE capability" information element describes the selective capability of the AP that supports the WLAN solution. Contains the fields used for. The "HE-enabled GI" field may be placed, for example, in the "HE capability" element and may be placed in the manner shown in FIG.

In the second selective implementation, the "HE-enabled GI" field is placed in the field of the "HE capability" element. As shown in FIG. 7, the "HE capability" element includes an "HE capability information" field, which is used to indicate the AP's capability information. The "HE-enabled GI" field may be placed in the "HE capability information" field above.

In the present invention, the newly added field, namely the "HE-enabled GI" field, indicates the data GI length supported by the AP, and in the new generation standard HEW solution, the bandwidth supported by the AP is 20MHz, 40MHz, 80MHz. , Or 160 MHz. As shown in Figure 8, there are multiple GI lengths at various bandwidths. The data GI length supported by the AP is N (N = 1, 2, 3, ..., 32) x 0.4 us. The "HE-enabled GI" field can be represented in multiple ways. Although some representations are used separately below as examples for illustration, it should be noted that the present specification is not limited to any particular representation.

In the first selective implementation, the newly added field contains an indicator value corresponding to each preset bandwidth, which the access device can use within the preset bandwidth. Represents the minimum data guard interval length for all supported data guard interval lengths, and preset bandwidths may include 20MHz, 40MHz, 80MHz, and 160MHz. For ease of explanation, a particular representation method randomly picks M data GI lengths from all data GI lengths supported by the various bandwidths shown in the table in Figure 8 as GI lengths supported by the AP. It may be a choice, which is shown in Figure 9. N is a serial number, and the value of N is {1, 2, ... .. .. , M}, m represents the bit amount of the indicating bit, and N corresponds to the value of the indicating bit on a one-to-one basis. Assuming that 6 data GI lengths are selected, M = 6, N = {1, 2, ... .. .. , 6}, m = 3, and the relationship between N and the indicator bit is as shown in FIG. For simplicity, assuming that the AP does not support some data GI lengths, a "-" indicates that the APs in the corresponding bandwidth do not support that GI length.

Assuming that the minimum data GI length supported by the AP is min_GI, the index value corresponding to min_GI is N, and each of the various bandwidths corresponds to one min_GI. FIG. 10 shows the min_GI supported by the AP in various bandwidths and the relationship between the min_GI and the serial number and the indicating bit obtained by FIG.

The indicated index value included in the "HE compatible GI" field refers to the index value corresponding to min_GI indicated by the "HE compatible GI" field in various bandwidths. The index value corresponding to min_GI indicated by the "HE-enabled GI" field in various bandwidths refers to the serial number corresponding to min_GI supported in each bandwidth and carried by the "HE-enabled GI" field. For example, the data GI lengths supported in the 20MHz bandwidth are {0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}. Assuming that the min_GI supported in the 20MHz bandwidth is 0.8us, the indicator value of the 20MHz serial number is 2. Refer to 20MHz processing to process 40MHz, 80MHz, and 160MHz. Specifically, the indicator index value of the "HE-compatible GI" field in the beacon frame is represented in a binary coded format, that is, in the format of an indicator bit, and a specific representation format is shown in FIG. The “HE-enabled GI” field includes an indicator value for each preset bandwidth, and the indicator value GI_Idx is represented by bit information. A specific bit information representation is shown in FIG.

In the second selective implementation, the newly added field contains an indicator bit for each preset data guard interval length, which indicates whether the access device supports the preset data guard interval length. Used to indicate. In this implementation method, the influence of bandwidth is not considered, and M data GI lengths are selected as preset data GI lengths from the data GI lengths shown in FIG. For example, the preset data GI length is {0.4us, 0.8us, 1.2us, 1.6us, 2.0us, 2.4us, 2.8us, 3.2us}.

The HE-enabled GI field uses an indicator bit to indicate whether the AP supports preset data GI lengths. The "HE-enabled GI" field may use a single bit of indicator bit to indicate each data GI length in all preset data GI lengths, and each bit information bit indicates one data GI length. The representation of the "HE-enabled GI" field is shown in Figure 13, where one bit indicates one data GI length. Specific bit information indications are shown in FIG.

In a third selective implementation, the newly added field contains an indicator bit for each preset data guard interval length within each preset bandwidth, and the indicator bits are preset by the access device. Used to indicate whether preset data guard interval lengths within the bandwidth are supported. In this embodiment, as shown in FIG. 15, M data GI lengths are randomly selected from all the data GI lengths shown in FIG. 8 and are supported in various bandwidths as the data GI lengths supported by the AP. However, here M = 5. The "HE-enabled GI" field indicates the data GI length supported by each bandwidth means that the "HE-enabled GI" field uses a single-bit indicator bit to indicate the data GI length supported by the AP. That is, each bit separately indicates the data GI lengths supported by the various bandwidths, and the representation of the "HE-enabled GI" field is shown in Figure 16. Specific bit information is shown in FIGS. 17A and 17B.

Optionally, the access device broadcasts the constructed beacon frame, and the particular broadcast method may be to encapsulate the beacon frame in PPDU format for broadcasting. There may be multiple PPDU format encapsulation methods. For example, the beacon frame may be encapsulated in PPDU1 by the existing standard 802.11ac, or by the new generation standard HEW so that terminals supporting the new generation standard HEW can identify and analyze PPDU2. Another encapsulation method may be created to encapsulate the beacon frame in PPDU2, but see the description in Figure 3 for a specific creation method.

When terminal STA1 supporting the 802.11ac standard and terminal STA2 supporting the new generation standard HEW coexist within the broadcast range, the access device AP encapsulates both STA1 and STA2 so that they can access the network. Encapsulated PPDU1 and PPDU2 need to be broadcast. The broadcast method of PPDU1 may be to broadcast PPDU1 during a specific period preset by existing standards. A calculated field may be added to PPDU1 to broadcast PPDU2, but the calculated field may indicate the broadcast time of PPDU2 as it broadcasts PPDU2 at the time indicated by the calculated field.

After receiving the beacon frame broadcast by the AP and encapsulating it in PPDU1 format, STA1 accesses the network according to the existing 802.11ac standard. After detecting PPDU1 and / or PPDU2, STA2 analyzes the beacon frame, analyzes each capability element of the beacon frame, analyzes the "HE-enabled GI" field of the capability element, and determines the data GI length supported by the AP. get. STA2 obtains the available data GI length used for communication with the AP by the data GI length supported by STA2, but the available data GI length matches the data GI length supported by STA2. And refer to the data GI length in the data GI length supported by the AP. For example, the data GI lengths supported by STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, and the data GI lengths supported by AP are {0.4us, 0.8us, 1.6us. , 2.0us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us, 2.4us, 3.2us}, in this case {0.8us, 1.6us, 2.4us, 3.2us} is the available data GI length. Subsequently, STA2 performs data communication with the AP by using a selectable data GI length. Specifically, STA2 selects the data GI length from the available GI lengths according to the channel conditions. Data communication may be performed with the AP.

The processor is further configured to encapsulate the beacon frame into a first standard protocol data unit and a second standard protocol data unit.

The transceiver is further configured to broadcast a beacon frame encapsulated in a first standard protocol data unit and a beacon frame encapsulated in a second standard protocol data unit.

Optionally, consider the case where an STA that supports the first standard and an STA that supports the second standard coexist on the network. For example, STA1 supports the first standard and STA2 supports the second standard. The first or second standard above may be a different WIFI solution, an existing WIFI standard solution such as 802.11ac, or a new generation standard solution HEW currently under consideration by the standardization group. It may be, or it may be another similar WIFI solution.

When encapsulating the beacon frame in PPDU format, the access device AP must encapsulate the beacon frame in two PPDU formats, the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2. PPDU1 is obtained by encapsulation according to the first standard and PPDU2 is obtained by encapsulation according to the second standard.

Optionally, the access device broadcasts a beacon frame encapsulated in PPDU1 and a beacon frame encapsulated in PPDU2, but certain broadcast methods broadcast PPDU1 during a preset period of time. It may be to broadcast PPDU2 at the broadcast time. However, it is necessary to add a calculated field indicating the transmission time of PPDU2 to PPDU1.

Further, the processor obtains the maximum data guard interval length with the data guard interval length supported by the first standard access device, and further determines the maximum data guard interval length as the first alternative data guard interval length. It is composed.

Further, the processor obtains the maximum data guard interval length with the data guard interval length supported by the second standard access device, and further determines the maximum data guard interval length as the second alternative data guard interval length. It is composed.

The processor further encapsulates the beacon frame in the first standard protocol data unit and the second standard protocol data unit separately by the first alternative data guard interval length and the second alternative data guard interval length. It is composed.

Optionally, the AP separately supports a set of data GI lengths in the first standard and the second standard. The first alternative data GI length refers to the maximum data GI length in a set of GIs supported by the AP in the first standard. For example, if the data GI length supported by the first standard AP is {0.4us, 0.8us}, the first alternative data GI length refers to the data GI length of 0.8us.

Optionally, the AP also supports a second standard set of data GI lengths, and a second alternative data guard interval length is the maximum data of a set of GIs supported by the second standard AP. Refer to the GI length. For example, if the set of data GI lengths supported by the AP in the second standard is {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}, then the second alternative data GI length is , 3.2 Refer to the data length of us.

If there is a wider variety of STAs in the network that support different standards, that is, if there are multiple types of STAs, then different types of STAs support different standards, but STAs that support different standards. It should be noted that there may be compatibility between them. However, STA has only upward compatibility instead of backward compatibility. For example, a STA that supports HEW is compatible with a STA that supports the 802.11ac standard, but a STA that supports the 802.11ac standard is not compatible with a STA that supports HEW. For example, if there are multiple types of STAs on the network, the number of different standards supported by the various STAs in the network is 3, 4, or more, and the alternate data GI length is determined accordingly. In this case, the number of alternative data GI lengths may be correspondingly 3, 4, or more. For the sake of simplicity, assuming that the two STAs in the network support the first standard (such as the 802.11ac standard solution) and the second standard (such as the current HEW standard solution), respectively: The contents of the present invention will be described in the above, but the alternative data GI lengths are GI1 and GI2.

Optionally, the access device uses a first alternative data guard interval length GI1 and a second alternative data guard interval length GI2 to place the beacon frame on the first standard protocol data unit PPDU1 and the second standard protocol data unit. Encapsulated in PPDU2, but the constructed PPDU1 and PPDU2 must comply with the PPDU format in their respective standards. The formats of PPDU1 and PPDU2 will be described separately below.

As shown in FIG. 18, optionally, the PPDU1 format includes preamble and bearer data, the bearer data includes beacon frames, and the preamble GI length and data GI length in the PPDU1 format are GI1, respectively. The purpose of the AP sending PPDU1 is to make STA1 network discoverable, which supports the first standard. The first standard may be the 802.11ac standard.

Optionally, the second standard may be the HEW standard. With reference to the HEW standard, the PPDU2 format has multiple design methods, but is not limited to this. The design of three selective PPDU2 formats is shown below.

As shown in FIG. 19, in the first selective implementation, the PPDU2 contains a legacy preamble, a high efficiency radio local area network preamble, and bearer data, a combination of L-STF, L-LTF, and L-SIG. Is called a legacy preamble, and a combination of HE-SIG, HE-STF, and another possible field is called a HEW preamble. The GI length of the legacy preamble, the GI length of the HEW preamble, and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. Note that STA2 can also detect PPDU1 and process PPDU1. A description of all the fields in FIG. 19 is shown in FIG.

As shown in Figure 21, in the second selective implementation, the PPDU2 format includes a legacy preamble, a high efficiency radio local area network preamble, and bearer data, the legacy preamble has a GI length of GI1 and a HEW preamble. The GI length of the bearer data and the GI length of the bearer data are GI2, respectively. The purpose of the AP sending PPDU2 is to make STA2 network discoverable, which supports the second standard. The length of the PPDU2 format legacy preamble in the first selective implementation, obtained from Figure 20, is 80us. The length of the PPDU2 format legacy preamble in the second selective implementation, obtained from FIG. 22, is 20us. If the remaining field lengths are the same, the second selective practice reduces the transmission overhead by 60us. A description of all the fields in FIG. 21 is shown in FIG.

In a third selective implementation, the PPDU2 format is shown in Figure 23, where PPDU2 contains highly efficient radio local area network preambles and bearer data. A description of all the fields in FIG. 23 is shown in FIG. The GI length of the HEW preamble and the GI length of the bearer data are GI2 respectively, and the purpose of the AP to send PPDU2 is to make STA2 network discoverable, which supports the second standard. Compared to the PPDU format in the first selective implementation, the PPDU format in the third selective implementation removes the legacy preamble. Therefore, if the remaining field lengths are the same, the transmit overhead is reduced by 80us compared to the PPDU format in the first selective implementation.

The processor is further configured to add to the first standard protocol data unit an arithmetic field used to indicate the transmission time of the second standard protocol data unit.

The transceiver is further configured to broadcast a first standard protocol data unit containing computational fields for a preset period of time.

The transceiver is further configured to broadcast a second standard protocol data unit at the transmit time indicated by the calculated field.

Optionally, the AP sends the constructed PPDU1 and PPDU2. Assuming that PPDU1 is constructed by the 802.11ac standard, the transmission period of PPDU1 specified by the 802.11ac standard is T1, and the transmission time of PPDU2 by the AP may be specified randomly, and the AP is For example, PPDU1 and PPDU2 are transmitted alternately. A calculated field may be added to PPDU1 for display, or a calculated field may be added to PPDU2 for display. The calculated field is used to indicate the transmission time of PPDU2. The calculated field may indicate the transmission time of PPDU2 in a plurality of display methods, but only two methods are described below.

In the first selective implementation, the HE calculated field uses only one bit to indicate whether the next m * T (eg, m = 2/3) period has PPDU2, where , T is the preset period for broadcasting PPDU1. That is, if the value of the HE calculated field is 1, it means that the next m * T period has PPDU2, and if the value of the HE calculated field is 0, the next m * T period does not have PPDU2. Show that. As shown in FIG. 25, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 0, it does not have PPDU2 during the next m * T period.

In the second selective implementation, the HE calculated field has two or more bits, represented as x bits. The HE calculated field may be used to indicate whether the next (n + m * T) period (eg, m = 2/3, where n is a natural number indicated by x bits) has PPDU2. That is, if the value of the HE operation field is n, the next (n + m * T) period is PPDU2.
Indicates that it has. As shown in FIG. 26, since the value of the HE calculated field of the first PPDU1 from the left is 1, it indicates that the next m * T period has PPDU2, and the value of the HE calculated field of the second PPDU1 is Since it is 2, the next two m * T periods have PPDU2.

Optionally, the access device broadcasts a PPDU 1 containing a calculated field during a particular preset period. PPDU1 may be encapsulated by the 802.11ac standard, and therefore PPDU1 may be broadcast by a period preset in the 802.11ac standard.

Optionally, as shown in FIG. 25 or 26, the access device broadcasts PPDU2 at the transmit time indicated by the calculated field. Upon receiving PPDU1, the terminal may know the transmission time of PPPDU2 from the calculated field, or may receive PPDU2 at the known transmission time.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

With reference to FIG. 31, FIG. 31 is a schematic configuration diagram of another terminal according to the present invention. The terminal 40 of FIG. 31 may be configured to implement all the steps and methods in the embodiment of the above method. In the embodiment of FIG. 31, terminal 40 includes processor 400, transceiver 401, memory 402, antenna 403, and bus 404. The processor 400 controls the operation of the terminal 40, but can also be configured to process the signal. Memory 402 may include read-only memory and random access memory to provide instructions and data for processor 400. The transceiver 401 may be connected to the antenna 403. The components within terminal 40 are connected together by using bus system 404, which bus system 404 further includes a power supply bus, a control bus, and a status signal bus in addition to the data bus. However, for the sake of clarity, the figure shows the various buses as the bus system 404. For example, the terminal 40 may be STA1, STA2, and STA3 shown in FIG. In the following, all the components of the terminal 40 will be described in detail.

The transceiver is configured to capture the beacon frame broadcast by the access device, where the beacon frame contains a newly added field and the newly added field is a multiple data guard interval supported by the access device. Represents the length.

The processor is configured to select from a plurality of data guard interval lengths supported by the access device an available guard interval length that matches the data guard interval length supported by the terminal.

The transceiver is configured to perform data communication with the access device by using the available guard interval length.

Optionally, the terminal STA acquires the beacon frame broadcast by the access device, but the beacon frame may be a beacon frame, the beacon frame includes a newly added field, and the newly added field. Represents multiple data GI lengths supported by the access device. The processing procedure of STA corresponds to the processing procedure of the access device AP described above. The AP side encapsulates the beacon frame in the first standard protocol data unit PPDU1 and the second standard protocol data unit PPDU2, but the first standard may be the 802.11ac standard and the second standard is It may be a HEW standard. In this embodiment, if STA1 supporting the first standard and STA2 supporting the second standard are present on the network, STA1 can perform normal detection processing only in PPDU1. The detection processing method is not described in detail here, but refer to the 802.11ac standard solution. The STA processing procedure described here refers to the above STA2 processing procedure.

The AP transmits PPDU1 during a preset period, which contains a calculated field used to indicate the transmission time of PPDU2, which indicates the transmission time of PPDU2. Specifically, there are three selective implementations of the method used by the STA to capture beacon frames broadcast by the AP.

In the first selective implementation, when the STA gets the PPDU1 broadcast by the AP, the STA processes the PPDU1 and parses the beacon frame from the PPDU1 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU1. For example, if the preamble of PPDU1 is GI1, the STA sets the preamble for subsequent data communication to GI1.

In the second selective implementation, when the STA gets the PPDU2 broadcast by the AP, the STA processes the PPDU2 and parses the beacon frame from the PPDU2 while at the same time in subsequent data communication between the STA and the AP. The preamble length is determined by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

In the third selective implementation method, when the STA receives PPDU1, the STA obtains the transmission time of the next PPDU 2 from PPDU 1 by analyzing the "HE operation" field. For example, if the "HE operation" uses bits to indicate whether the next period has PPDU2, then if the "HE operation" field indicates 0, then the STA must detect PPDU2 in the next period. If there is, or if the "HE Calculator" field shows 1, it indicates that the STA does not need to detect PPDU2 during the next period. STA analyzes the beacon frame from the detected PPDU2. In addition, the STA determines the preamble length for subsequent data communication between the STA and AP by the preamble of PPDU2. For example, if the preamble of PPDU2 is GI2, the STA sets the preamble for subsequent data communication to GI2.

Optionally, the terminal STA analyzes the beacon frame after acquiring the beacon frame. The specific analysis method is that the STA detects all the capability elements of the beacon frame and analyzes the "HE-enabled GI" field to obtain the data GI length supported by the AP, and the STA supports the STA. It may be to set the available GI length based on the data GI length and the acquired data GI length supported by the AP. For example, if the data GI length indicated by the information about the "HE compatible GI" field is {0.8us, 1.6us, 2.4us}, the data GI length supported by the AP is {0.8us, 1.6us. , 2.4us}. The GI lengths supported by the STA itself are {0.4us, 0.8us, 1.6us, 2.4us, 3.2us}. The data GI lengths supported by both AP and STA2 are {0.8us, 1.6us}, in which case {0.8us, 1.6us} is the available data GI length. In the subsequent communication between the STA and AP, the data GI length is selected from the available data GI lengths according to the channel state to construct a PPDU.

After optionally obtaining the available data GI length, the STA may perform data communication with the AP by using the available data GI length. Specifically, in the subsequent communication between the STA and the AP, the data GI length is selected from the available data GI lengths according to the channel state to construct the PPDU.

In addition, the STA generates an association request frame based on the available data GI length and sends the association request frame to the AP. After receiving the association request frame, the AP analyzes the association request frame and returns the association response frame to the STA if the STA is allowed access to the network. After receiving the association response frame, the STA analyzes the association response frame. In this case, the STA may establish an association with the AP, after which the AP and STA may perform data communication for data transmission.

The transceiver is further configured to take the first standard protocol data unit broadcast by the access device and analyze the beacon frame from the first standard protocol data unit, or the transceiver is a second standard broadcast by the access device. The standard protocol data unit is acquired and further configured to parse the beacon frame from the second standard protocol data unit, or the transceiver acquires the first standard protocol data unit broadcast by the access device and the first The transmission time of the second standard protocol data unit is determined from the arithmetic field in the standard protocol data unit of 1, the second standard protocol data unit is acquired by the transmission time, and the beacon frame is obtained from the second standard protocol data unit. Further configured to analyze.

In this embodiment of the invention, the access device constructs a beacon frame, the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. , The access device broadcasts the constructed beacon frame, and the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the beacon frames broadcast by the access device, and the available guard Communicate with the access device by using the interval length. In this embodiment, the standard that proposes a plurality of data guard interval lengths sets a plurality of data guard interval lengths supported by the access device as beacon frames in order to normally execute data communication between the access device and the terminal. May be encapsulated in the newly added field of.

One of ordinary skill in the art may understand that all or part of the process of the method of the embodiment can be performed by a computer program that directs the relevant hardware. The program may be stored on a computer-readable storage medium. When the program is executed, the process of the method of the embodiment is executed. Examples of the storage medium include a magnetic disk, an optical disk, a read-only memory (ROM), a random access memory (RAM), and the like.

What has been disclosed above is merely an exemplary embodiment of the present invention and does not limit the scope of protection of the present invention. Therefore, equivalent modifications made based on the claims of the present invention shall be included within the scope of the present invention.

30 Access device
40 terminals
100 build module
101 Encapsulation module
102 Processing module
103 transceiver module
200 transceiver module
201 Selection module
300 processor
301 transceiver
302 memory
303 antenna
304 Bus, Bus System
400 processors
401 transceiver
402 memory
403 antenna
404 bus, bus system
1030 1st acquisition unit
1031 Second acquisition unit
1032 encapsulation unit

The present invention relates to the field of data communication technology, and more particularly to data communication methods and related devices.

Claims (22)

A step of constructing a beacon frame by an access device, wherein the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. Steps and
Data communication with the access device by the terminal selecting an available guard interval length from the beacon frame that matches the data guard interval length supported by the terminal and using the available guard interval length. And the step that the access device broadcasts the beacon frame so that
Data communication methods, including. The beacon frame contains at least one element, a specific element within the at least one element carries the newly added field, and the specific element is an existing element or a newly added element. , The method of claim 1. The newly added field contains an indicator value corresponding to each preset bandwidth, and the indicator value is all data guard interval lengths supported by the access device within the preset bandwidth. The newly added field represents the minimum data guard interval length of, or the newly added field contains an indicator bit of each preset data guard interval length, the indicator bit being the data guard for which the access device is preset. Used to indicate whether interval length support is supported, or said newly added field contains an indicator bit for each preset data guard interval length within each preset bandwidth. The method of claim 2, wherein is used to indicate whether the access device supports the preset data guard interval length within the preset bandwidth. After the step of constructing the beacon frame by the access device,
The access device further comprises the step of separately encapsulating the beacon frame into a first standard protocol data unit and a second standard protocol data unit.
The step in which the access device broadcasts the beacon frame
1. The access device includes a step of broadcasting the beacon frame encapsulated in the first standard protocol data unit and the beacon frame encapsulated in the second standard protocol data unit. The method described in. The plurality of data guard interval lengths supported by the access device are the data guard interval length supported by the access device in the first standard and the data guard interval length supported by the access device in the second standard. Including
The step of separately encapsulating the beacon frame into a first standard protocol data unit and a second standard protocol data unit by the access device.
The access device acquires the maximum data guard interval length in the data guard interval length supported by the access device in the first standard, and uses the maximum data guard interval length as the first alternative data guard interval length. Steps to decide and
The access device acquires the maximum data guard interval length in the data guard interval length supported by the access device in the second standard, and uses the maximum data guard interval length as the second alternative data guard interval length. Steps to decide and
With the first alternative data guard interval length and the second alternative data guard interval length, the access device separates the beacon frame into the first standard protocol data unit and the second standard protocol data unit. The steps to encapsulate and
4. The method of claim 4. The first standard protocol data unit includes preamble and bearer data, the bearer data includes the beacon frame, and the guard interval length of the preamble and the guard interval length of the bearer data are the first alternative data guard. The method of claim 5, which is the interval length. The second standard protocol data unit includes legacy preambles, high efficiency radio local area network preambles, and bearer data, including the legacy preamble guard interval length, the high efficiency radio local area network preamble guard interval length, and the bearer. The data guard interval lengths are, respectively, the second alternative data guard interval length, or
The second standard protocol data unit includes legacy preambles, high efficiency radio local area network preambles, and bearer data, and the guard interval length of the legacy preamble is the first alternative data guard interval length, said high. The guard interval length of the efficiency wireless local area network preamble and the guard interval length of the bearer data are the second alternative data guard interval length, or
The second standard protocol data unit includes high-efficiency wireless local area network preamble and bearer data, and the guard interval length of the high-efficiency wireless local area network preamble and the guard interval length of the bearer data are both the second. Alternate data guard interval length,
The method of claim 5. Prior to the step in which the access device broadcasts the beacon frame encapsulated in the first standard protocol data unit and the beacon frame encapsulated in the second standard protocol data unit.
It further comprises the step of the access device adding to the first standard protocol data unit a calculated field used to indicate the transmission time of the second standard protocol data unit.
The step in which the access device broadcasts the beacon frame encapsulated in the first standard protocol data unit and the beacon frame encapsulated in the second standard protocol data unit.
A step of broadcasting the first standard protocol data unit containing the calculated field during a preset period of time by the access device.
A step in which the access device broadcasts the second standard protocol data unit at the transmission time indicated by the calculated field.
5. The method of claim 5. A step in which the terminal acquires a beacon frame broadcast by the access device, wherein the beacon frame includes a newly added field, and the newly added field is a plurality of data guard intervals supported by the access device. Steps and steps that represent length
A step in which the terminal selects an available guard interval length that matches the data guard interval length supported by the terminal from the plurality of data guard interval lengths supported by the access device.
A step in which the terminal performs data communication with the access device by using the available guard interval length.
Data communication methods, including. The beacon frame is encapsulated in a first standard protocol data unit and a second standard protocol data unit, and the access device transmits the first standard protocol data unit during a preset period, and the first standard protocol data unit is transmitted. 9. The method of claim 9, wherein the standard protocol data unit of the second standard protocol data unit comprises a calculated field used to indicate a transmission time of the second standard protocol data unit. The step in which the terminal acquires the beacon frame broadcast by the access device is
A step in which the terminal acquires the first standard protocol data unit broadcast by the access device and analyzes the beacon frame from the first standard protocol data unit, or
A step in which the terminal acquires the second standard protocol data unit broadcast by the access device and analyzes the beacon frame from the second standard protocol data unit, or
The terminal acquires the first standard protocol data unit broadcast by the access device, and determines the transmission time of the second standard protocol data unit from the calculation field in the first standard protocol data unit. , The step of acquiring the second standard protocol data unit according to the transmission time and analyzing the beacon frame from the second standard protocol data unit.
10. The method of claim 10. It's an access device
Building a beacon frame, wherein the beacon frame includes a newly added field, and the newly added field represents a plurality of data guard interval lengths supported by the access device. That and
A transceiver configured to broadcast the beacon frame and perform data communication with the terminal.
Access devices, including. The beacon frame contains at least one element, a specific element within the at least one element carries the newly added field, and the specific element is an existing element or a newly added element. , The access device according to claim 12. The newly added field contains an indicator value corresponding to each preset bandwidth, and the indicator value is all data guard interval lengths supported by the access device within the preset bandwidth. Represents the minimum data guard interval length in, or
The newly added field contains an indicator bit for each preset data guard interval length, which is used to indicate whether the access device supports the preset data guard interval length. Be done or
The newly added field contains an indicator bit of each preset data guard interval length within each preset bandwidth, and the indicator bit is the preset that the access device has within the preset bandwidth. Used to indicate whether the data guard interval length is supported,
The access device according to claim 13. The access device further comprises an encapsulation module configured to encapsulate the beacon frame separately in a first standard protocol data unit and a second standard protocol data unit.
The transceiver module is specifically configured to broadcast the beacon frame encapsulated in the first standard protocol data unit and the beacon frame encapsulated in the second standard protocol data unit. The access device according to claim 12. The plurality of data guard interval lengths supported by the access device are the data guard interval length supported by the access device in the first standard and the data guard interval length supported by the access device in the second standard. Including, the encapsulation module
The maximum data guard interval length in the data guard interval length supported by the access device in the first standard is acquired, and the maximum data guard interval length is determined as the first alternative data guard interval length. With the first acquisition unit that was
The maximum data guard interval length in the data guard interval length supported by the access device in the second standard is acquired, and the maximum data guard interval length is determined as the second alternative data guard interval length. With the second acquisition unit that was
The first alternative data guard interval length and the second alternative data guard interval length so that the beacon frame is separately encapsulated in the first standard protocol data unit and the second standard protocol data unit. With the configured encapsulation unit
15. The access device of claim 15. The first standard protocol data unit includes preamble and bearer data, the bearer data includes the beacon frame, and the guard interval length of the preamble and the guard interval length of the bearer data are the first alternative data guard. The access device of claim 163, which is the interval length. The second standard protocol data unit includes legacy preambles, high efficiency radio local area network preambles, and bearer data, including the legacy preamble guard interval length, the high efficiency radio local area network preamble guard interval length, and the bearer. The data guard interval lengths are, respectively, the second alternative data guard interval length 3 or
The second standard protocol data unit includes legacy preambles, high efficiency wireless local area network preambles, and bearer data, and the guard interval length of the legacy preamble is the first alternative data guard interval length, said high. The guard interval length of the efficiency radio local area network preamble and the guard interval length of the bearer data are the second alternative data guard interval length, or
The second standard protocol data unit includes high-efficiency wireless local area network preamble and bearer data, and the guard interval length of the high-efficiency wireless local area network preamble and the guard interval length of the bearer data are both the second. Alternate data guard interval length,
The access device according to claim 16. The access device
It further includes a processing module configured to add to the first standard protocol data unit an arithmetic field used to indicate the transmission time of the second standard protocol data unit.
The transceiver module is specifically configured to broadcast the first standard protocol data unit, including the calculated field, for a preset period of time.
The transceiver module is further configured to broadcast the second standard protocol data unit at the transmit time indicated by the calculated field.
The access device of claim 163. It ’s a terminal,
From the plurality of data guard interval lengths supported by the access device, an available guard interval length that matches the data guard interval length supported by the terminal is selected.
A transceiver configured to acquire a beacon frame broadcast by an access device, wherein the beacon frame includes a newly added field, and the newly added field is a plurality of fields supported by the access device. A transceiver that represents the data guard interval length,
Including
The transceiver is further configured to perform data communication with the access device by using the available guard interval length.
Terminal. The beacon frame is encapsulated in a first standard protocol data unit and a second standard protocol data unit, and the access device transmits the first standard protocol data unit during a preset period, and the first standard protocol data unit is transmitted. 20. The terminal of claim 20, wherein the standard protocol data unit of the second standard protocol data unit includes a calculated field used to indicate a transmission time of the second standard protocol data unit. The transceiver is specifically configured to acquire the first standard protocol data unit broadcast by the access device and analyze the beacon frame from the first standard protocol data unit.
The transceiver is specifically configured to acquire the second standard protocol data unit broadcast by the access device and analyze the beacon frame from the second standard protocol data unit.
The transceiver acquires the first standard protocol data unit broadcast by the access device and determines the transmission time of the second standard protocol data unit from the arithmetic field in the first standard protocol data unit. The terminal according to claim 21, wherein the second standard protocol data unit is acquired according to the transmission time, and the beacon frame is specifically analyzed from the second standard protocol data unit.

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