KR20100085871A - Method and apparatus for transmitting/receiving data in wireless communication network - Google Patents

Abstract

PURPOSE: A method and an apparatus for transmitting and receiving data in a wireless communication network are provided to improve the through of an entire system by allocating the resources for data transmission and reception only to the stations of a VHT system in a set protection section. CONSTITUTION: It is informed that a non-VHT-station exists in a wireless communication network(122), and a message indicating that data are supposed to be transmitted to plural VHT-stations is transmitted for the non-VHT-station and a VHT-station which exist in the wireless communication network(124). The resource allocation information for the plural VHT-stations is transmitted(126), and the data are transmitted to the plural VHT-stations according to the resource allocation information(130).

Description

METHOD AND APPARATUS FOR TRANSMITTING / RECEIVING DATA IN WIRELESS COMMUNICATION NETWORK}

The present invention relates to a method and apparatus for transmitting and receiving data, and more particularly, to a method and apparatus for transmitting and receiving data in a wireless communication network.

The present invention is derived from the research conducted as part of IPTV convergence service advancement support technology development project of the Korea Communications Commission. [Task Management Number: 2009-S-004-01, Title: Development of Supporting Technology for IPTV Convergence Service]

In a wireless LAN system, when a plurality of stations simultaneously transmit data to an access point, the size of data transmitted by each station may be different. Of course, the same is also true when the access point simultaneously transmits data to a plurality of stations. Moreover, as recent researches on high-capacity wireless transmission technologies such as Very High Throughput (VHT), which can transmit data at a speed of Gbps, are simultaneously performed in a wireless communication network in which a station of a VHT system and a station of an existing system before VHT coexist. Due to the different data sizes, the following problems are exacerbated.

For example, when a station of a VHT system and a station of a system before the VHT simultaneously transmit data to an access point, the data of the station of the VHT system is large and the size of the data transmitted by the station of the system before the VHT is large. It is quite large compared to If a station of a VHT system and a station of a system before the VHT allow each station to transmit data in accordance with a minimum size of data to be transmitted, the purpose of a large data transmission such as a transmission for a large-capacity multimedia cannot be achieved. This happens. On the contrary, if each station transmits the data according to the maximum size of the data that the station of the VHT system and the station before the VHT intend to transmit, the resources allocated to the station of the system that does not transmit a large amount of data are wasted. A problem occurs.

Accordingly, the present invention is to solve the above problems, and a method and apparatus for transmitting and receiving data to improve the throughput of the system by efficiently distributing resources in a wireless communication network where the station of the VHT system and the station of the existing system before the VHT coexist The purpose is to provide.

The objects of the present invention are not limited to the above-mentioned objects, and other objects and advantages of the present invention, which are not mentioned above, can be understood by the following description, and more clearly by the embodiments of the present invention. It will also be appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

A data transmission method according to an embodiment of the present invention for achieving the above object is a method for transmitting data to a plurality of Very High Throughput (VHT) -station in the wireless communication network in the wireless communication network, notifying that a non-VHT-station exists, and transmitting a message indicating that data is to be transmitted to the plurality of VHT-stations for non-VHT-stations and VHT-stations existing in the wireless communication network. Transmitting resource allocation information for the plurality of VHT-stations; and transmitting the data to the plurality of VHT-stations according to the resource allocation information.

According to the present invention, in a wireless communication network in which a station of a VHT system and a station of an existing system before VHT coexist, a protection period for a station of the VHT system is set and a resource for data transmission and reception is set in the protection period. By assigning only to stations in the system, throughput of the entire system can be improved.

In addition, according to the present invention, by transmitting and receiving data by distributing time resources between stations of the VHT system within the set guard interval, it is possible to use the resource more efficiently.

1 is a flowchart illustrating a method of transmitting data to a plurality of VHT-STAs in a VHT-AP according to an embodiment of the present invention.
2 is a diagram illustrating a method for transmitting data to a plurality of VHT-STAs in a VHT-AP according to another embodiment of the present invention.
3 is a flowchart illustrating a method of transmitting data from a VHT-STA to a VHT-AP according to an embodiment of the present invention.
4 is a diagram illustrating a method for transmitting data from a VHT-STA to a VHT-AP according to another embodiment of the present invention.
5 is a diagram illustrating resource allocation information according to an embodiment of the present invention.

The above objects, features, and advantages will be described in detail with reference to the accompanying drawings, whereby those skilled in the art to which the present invention pertains may easily implement the technical idea of the present invention. In describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description will be omitted. Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals are used to indicate the same or similar components.

The present invention provides a multi-user multi-input multi-output in transmitting and receiving data between an access point (AP) and a station (STA) in a wireless communication network. The following 'MU-MIMO' system can be applied.

In the present invention, the AP and STA in the VHT (Very High Throughput) system, which is a standard newly discussed in IEEE 802.11.ac, are referred to as VHT-AP and VHT-STA, respectively, and the existing system before VHT (hereinafter referred to as 'non-VHT system'). ) Is called non-VHT-STA. Wireless LANs (WLANs) Newly evolving specifications in 802.11 are required to coexist with existing specifications. Therefore, when the VHT-AP controls a wireless communication network in which the VHT-STA and the non-VHT-STA coexist, a control method for extending to a new standard without violating the existing standard is required.

However, the method of controlling VHT-AP to simultaneously transmit data to VHT-STA and non-VHT-STA or to simultaneously receive data from VHT-STA and non-VHT-STA, considering the characteristics of the STA of each system Not only is it complicated to control, it is also inefficient in terms of throughput of the entire system. That is, as described above, since VHT-STA transmits and receives a large amount of data compared to non-VHT-STA, when VHT-STA and non-VHT-STA transmit or receive data at the same time, it is allocated to non-VHT-STA. The wasted resources waste the throughput of the entire system.

Therefore, in the wireless communication network in which VHT-STA and non-VHT-STA coexist, a protection period for VHT-STA is set, and the resource for transmitting / receiving data is set to VHT-STA only in the protection period. By assigning, the throughput of the whole system is improved.

In addition, the present invention enables more efficient resource use by transmitting and receiving data by distributing time resources between VHT-STAs within a set guard period.

Hereinafter, a case in which a VHT-AP transmits data to a plurality of VHT-STAs in a wireless communication network in which at least one VHT-STA coexists with at least one non-VHT-STA will be described with reference to FIGS. 1 and 2. Of course, the present invention can also be applied to the case where the VHT-AP transmits data to one VHT-STA. In the embodiment described with reference to FIG. 2, the VHT-AP 100 transmits data 214 of different sizes to the VHT-STA1 102, the VHT-STA2 104, and the VHT-STA3 106.

First, the VHT-AP notifies that there is a non-VHT-STA in the wireless communication network (122). This means that the method disclosed in the present invention is used to transmit and receive data between the VHT-AP and the VHT-STA.

As an example, referring to FIG. 2, the VHT-AP 100 may inform that a non-VHT-STA 108 exists in a wireless communication network through a beacon frame (202). For example, the VHT-AP 100 may include time sharing information indicating whether a non-VHT-STA exists in a wireless communication network in the beacon frame. That is, when time sharing information in the beacon frame is ON, since the non-VHT-STA 108 exists in the wireless communication network, a guard interval for data transmission and reception between the VHT-AP and the VHT-STA. Indicates that the time resource distribution function between the configuration and the VHT-STA is used. When the time sharing information is OFF, since only VHT-STAs exist in the wireless communication network, it indicates that resources are allocated by applying a resource occupancy procedure used in an existing system before VHT.

The VHT-AP which wants to transmit data to the VHT-STAs transmits a message to all non-VHT-STAs and all VHT-STAs indicating that it is going to use a radio resource (124).

As an example, referring to FIG. 2, the VHT-AP 100, which intends to transmit data to the VHT-STAs 102, 104, and 106, may have a protection interval (200) after a DIFS (Distributed InterFrame Space) time. In operation 204, a message indicating that the radio resource is to be used is transmitted in the form of a non-VHT Physical Layer Protocol Data Unit (PPDU). The guard period 200 refers to a period in which radio resources are allocated only for VHT-STAs except for non-VHT-STAs. The non-VHT PPDU is a packet of the PHY physical layer used in the non-VHT system, and both VHT-STAs 102, 104, 106 and 110 and non-VHT-STAs 108 can be received. At this time, since the non-VHT PPDU has only one Receiver Address (RA) field, the VHT-AP 100 has its own address in the Recipient Address (RA) field in the non-VHT PPDU. Send the information.

The non-VHT-STAs 108 set their Network Allocation Vector (NAV) value as the Duration field value in the received non-VHT PPDU (206). At this time, the duration field value in the non-VHT PPDU coincides with the guard interval 200. The NAV indicates that the AP or another STA has access to a radio resource for a set time. Thus, the non-VHT-STAs 108 do not attempt to acquire radio resources for a time set to the NAV 206 value. In this way, it is possible to prevent the non-VHT-STAs 108 from obtaining a radio resource while the VHT-AP 100 transmits data to the VHT-STAs 102, 104, 106.

The VHT-AP transmits resource allocation information for VHT-STAs to which data is to be transmitted to all VHT-STAs (126).

As an example, referring to FIG. 2, the VHT-AP 100 transmits a non-VHT PPDU 204 and after a Reduced InterFrame Space (RIFS) time, the VHT-STAs to which data is to be transmitted ( A message including resource allocation information for 102, 104, and 106 is transmitted in the form of a VHT PPDU (208). The VHT PPDU is a packet of the PHY physical layer used in the VHT system, and only VHT-STAs 102, 104, 106, and 110 may be received. In step 208, the VHT C-PPDU (Control PPDU) refers to a VHT PPDU serving to control data transmission and reception. In step 208, the VHT-AP 100 may transmit a VHT C-PPDU when the NAV value is 0 (zero) after performing the step 204 and the RIFS time has elapsed, and the VHT-STAs 102, 104, and 106 transmit the NAV value. When it is 0, VHT C-PPDU may be received.

Resource allocation information includes information on STAs to which resources are allocated and information on resources allocated to each STA. The information on the STAs to which the resource is allocated may be, for example, an address of the STAs to which the resource is allocated. Information on resources allocated to each STA includes, for example, antenna resources allocated to each STA, allocation time resources allocated to each STA, and the like. Hereinafter, a case in which the VHT-AP 100 transmits resource allocation information of FIG. 5 to the VHT-STAs 102, 104, 106, and 110 according to an embodiment will be described.

5 shows that the VHT-AP 100 allocates resources to the VHT-STA1 102, the VHT-STA2 104, and the VHT-STA3 106. Therefore, among the VHT-STAs 102, 102, 104, 106, and 110 that have received the resource allocation information, the VHT-STAs 110 with no resources assigned set the NAV value to the time until the guard interval 200 ends (210). In this case, the VHT-STAs 110 may set the NAV value by subtracting the time elapsed before receiving the VHT C-PPDU from the value of the Duration field in the non-VHT PPDU received in step 204. In addition, the NAV value may be set using a value set in the VHT C-PPDU by the VHT-AP 100. This may prevent the request for acquiring radio resources of other VHT-STAs 110 while the VHT-AP 100 transmits data to the VHT-STAs 102, 104, 106.

The VHT-AP receives an acknowledgment message for resource allocation information transmitted in step 126 from the VHT-STAs to which data is to be transmitted (128).

An embodiment will be described with reference to FIG. 2. If the VHT-AP 100 transmits the resource allocation information of FIG. 5 in step 208, the VHT-STAs 102, 104, 106 to which the resource is allocated among the VHT-STAs 102, 104, 106, and 110 receive the resource allocation information (FIG. 5). After the RIFS time elapses, acknowledgment messages Ack1, Ack2, and Ack3 for resource allocation information (FIG. 5) are transmitted to the VHT-AP 100 (212). In other words, the resource-allocated VHT-STAs 102, 104, and 106 know what resource is allocated to them through the resource allocation information (FIG. 5), and in response, the VHT-STAs 102, 104, and 106 receive the acknowledgment messages Ack1, Ack2, and Ack3. Transmit to the AP 100 (212).

The VHT-AP distributes resources according to resource allocation information and transmits data to the plurality of VHT-STAs (130).

As an example, referring to FIG. 2, the VHT-AP 100 receives resource allocation information (FIG. 5) from the VHT-STA1 102, the VHT-STA2 104, and the VHT-STA3 106. After receiving confirmation messages (Ack1, Ack2, Ack3) (212) and after the RIFS time has elapsed, the VHT-STA1 (102), VHT-STA2 (104) and VHT-STA3 (106) according to the resource allocation information (Fig. 5). Send data (214).

Hereinafter, a method in which the VHT-AP 100 and the VHT-STAs 102, 104, and 106 transmit and receive data according to the resource allocation information of FIG. 5 will be described.

Referring to FIG. 5, antenna # 0 is assigned to VHT-STA1 102 for 200 ms (microseconds), antenna # 1 is assigned to VHT-STA2 104 for 120 ms, and antenna # is assigned to VHT-STA3 106. 1 is allocated for 80ms. The VHT-STA2 104 and the VHT-STA3 106 share the same antenna resource # 1 in time. In the case where the same antenna resources are distributed and used in time, such as the VHT-STA2 104 and the VHT-STA3 106, in one embodiment, the allocated time resources may be given priority in a long order. have. In the present invention, the priority value excludes negative numbers. Therefore, 0 means the highest priority. Accordingly, the priority of the VHT-STA2 104 is 0 and the priority of the VHT-STA3 106 is 1. That is, antenna # 1 is first assigned to VHT-STA2 104 having a priority of 0 for 120 ms and then to VHT-STA3 106 having a priority of 1 for 80 ms.

In order to implement this, the VHT-STAs 104 and 106 allocated by temporally distributing the same antenna resource among the VHT-STAs 102, 104 and 106 may use NAV before receiving their data by using the resource allocation information (FIG. 5). Set the value (hereinafter 'BRNAV'). If the set BRNAV value is not zero, the BRNAV value is continuously decreased to start receiving data of the BRNAV when the BRNAV value becomes zero. The BRNAV value can be set by Equation 1 below.

Referring to Equation 1, each of the VHT-STA2 104 and VHT-STA3 106 each sums the allocation time of the VHT-STAs having a higher priority than their own priority (self_priority). Obtain the BRNAV value of.

Since the priority (self_priority) of the VHT-STA2 104 is 0, the BRNAV value of the VHT-STA2 104 becomes 0 according to Equation (1). Accordingly, VHT-STA2 104 sets the BRNAV value to zero (218). Since the BRNAV value is 0 (218), VHT-STA2 104 receives its data from antenna V1 through VHT-AP 100 (220).

Since the priority (self_priority) of the VHT-STA3 106 is 1, 120 ms of the allocation time of the VHT-STA2 104 having the priority of 0 becomes the BRNAV value of the VHT-STA3 106 according to Equation (1). Thus, VHT-STA3 106 sets the BRNAV value to 120 ms (226). Then, when the BRNAV value becomes 0 (228), the VHT-STA3 106 receives its data from the VHT-AP 100 via antenna # 1 (230).

Since the VHT-STA1 102 alone receives the antenna resource # 0 for 200 ms, the VHT-STA1 102 receives its data from the VHT-AP 100 through the antenna # 0 without setting a BRNAV value (216).

Furthermore, the VHT-STA2 104 and the VHT-STA3 106 using the same antenna resources in time distribution do not perform the data acknowledgment procedure immediately after receiving all of their own data. Wait until the data is received.

In order to implement this, the VHT-STAs 104 and 106 allocated by temporally distributing the same antenna resource among the VHT-STAs 102 and 104 and 106 are NAV after receiving their data using the resource allocation information (Fig. 5). Set the value (hereinafter 'ARNAV'). If the set ARNAV value is not 0, the data acknowledgment procedure is continuously performed when the ARNAV value becomes 0 by continuously decreasing the ARNAV value. The ARNAV value can be set by Equation 2 below.

Here, largest_priority is the lowest priority.

Referring to Equation 2, each of the VHT-STA2 104 and VHT-STA3 106 each sums the allocation time of the VHT-STAs having a priority lower than their own priority (self_priority). Obtain the ARNAV value of.

Since the priority (self_priority) of the VHT-STA2 104 is 0 and the largest_priority is 1, the ARNAV value of the VHT-STA2 106 is the allocation time of the VHT-STA3 106 having a priority of 1 according to Equation (2). 80 ms. Therefore, after receiving 220 data, VHT-STA2 104 sets the ARNAV value to 80ms (222). Then, when the ARNAV value becomes 0 (224), VHT-STA2 104 performs a data reception confirmation procedure to be described later.

Since the priority (self_priority) of the VHT-STA3 106 is 1 and the largest_priority is 1, the ARNAV value of the VHT-STA3 106 becomes 0 according to equation (2). Accordingly, after receiving data 230, VHT-STA3 106 sets the ARNAV value to 0 (232). Since the ARNAV value is 0, the VHT-STA3 106 performs a data acknowledgment procedure to be described later.

Since the VHT-STA1 102 alone has been allocated antenna resource # 0 for 200 ms, it is not necessary to set the ARNAV value. Accordingly, the VHT-STA1 102 receives 216 data and performs a data acknowledgment message procedure to be described later.

The VHT-AP receives an acknowledgment message for the data from the VHT-STAs receiving the data (132).

As an example, referring to FIG. 2, the VHT-STAs 102, 104, and 106 may perform the data acknowledgment procedure at the same time using the ARNAV value as described above. The data acknowledgment procedure refers to a procedure for transmitting information indicating whether the VHT-STAs 102, 104, and 106 have successfully received data to the VHT-AP 100. That is, the VHT-STAs 102, 104, and 106 transmit an acknowledgment message (ACKnowledgement: ACK) for data that has been successfully received and a negative acknowledgment message (Negative ACK: NACK) for data that has not been successfully received. Can be. In the present invention, the data acknowledgment procedure uses a block acknowledgment (Ack) format applied in 802.11n. That is, the VHT-STAs 102, 104, and 106 do not transmit an ACK each time they receive each frame, but collect and transmit ACKs for a plurality of frames received during a predetermined period at one time. At this time, the block Ack also transmits and receives time resources like the data transmission and reception. The time resource information allocated to the VHT-STAs 102, 104, and 106 for block Ack transmission and reception may be included in the resource allocation information of FIG. 5 according to an embodiment.

Among the VHT-STAs 102, 104, and 106, the VHT-STAs 104 and 106, which are allocated by temporally distributing the same antenna resource, use NAV (hereinafter, 'BTNAV') before transmitting their block Ack using the resource allocation information (FIG. 5). ') Set the value. If the set BTNAV value is not 0, it continuously decreases the BTNAV value and starts transmitting its own block Ack when the BTNAV value becomes 0. The BTNAV value may be set by Equation 3 below.

Referring to Equation 3, each of the VHT-STA2 104 and VHT-STA3 106 each sums the block Ack allocation times of the VHT-STAs having a higher priority than their own priority (self_priority), and their BTNAV. Find the value.

Since the priority (self_priority) of the VHT-STA2 104 is 0, the BTNAV value of the VHT-STA2 104 becomes 0 according to equation (3). Accordingly, the VHT-STA2 104 sets the BTNAV value to 0 after the RIFS time elapses (236). Since the BTNAV value is 0 (236), the VHT-STA2 104 transmits its block Ack (Block Ack2) to the VHT-AP 100 through the antenna # 1 (238).

Since the priority (self_priority) of the VHT-STA3 (106) is 1, the BTNAV value of the VHT-STA3 (106) has a block Ack allocation time of 12 ms of the VHT-STA2 (104) having a priority of 0 according to Equation (3). do. Accordingly, the VHT-STA3 106 sets the BTNAV value to 12ms after the RIFS time elapses (244). If the BTNAV value is 0 (246), the VHT-STA3 106 transmits its block Ack (Block Ack3) to the VHT-AP 100 through the antenna # 1 (248).

Since the VHT-STA1 102 alone is allocated antenna resource # 0 for 20 ms, it is not necessary to set the BTNAV value. Accordingly, the VHT-STA1 102 transmits its block Ack (Block Ack1) to the VHT-AP 100 through the antenna # 0 after the RIFS time elapses (234).

In addition, the VHT-STAs 104 and 106 that share and use the same antenna resource in time transmit their block Ack (Block Ack2 and Block Ack3), and then all of the VHT-STAs 102, 104 and 106 transmit the block Ack. Wait until you finish it. As a result, the VHT-AP 100 and the VHT-STAs 102, 104, and 106 may safely transmit and receive data during the guard period 200.

In order to implement this, the VHT-STAs 104 and 106 allocated by temporally distributing the same antenna resource among the VHT-STAs 102, 104 and 106 are able to transmit their block Ack using the resource allocation information (Fig. 5). Set NAV (hereinafter 'ATNAV') value. If the set ARNAV value is not 0, the time point at which the ARNAV value is continuously decreased by zero is the time point when all the VHT-STAs 102, 104, and 106 complete the transmission of the block Ack. The ATNAV value may be set by Equation 4 below.

Here, largest_priority is the lowest priority.

Referring to Equation 4, each of the VHT-STA2 104 and the VHT-STA3 106 each sums the block Ack allocation time of the VHT-STAs having a priority lower than its own priority (self_priority), and thus its ATNAV. Find the value.

Since the priority (self_priority) of the VHT-STA2 104 is 0 and the largest_priority is 1, the ATNAV value of the VHT-STA2 106 is a block of the VHT-STA3 106 having a priority of 1 according to equation (4). Ack allocation time is 8ms. Accordingly, the VHT-STA2 104 transmits a block Ack (Block Ack2) (238) and sets the ATNAV value to 8 ms (240). If the ATNAV value is zero (242), then all of the VHT-STAs 102, 104, and 106 transmit a block Ack.

Since the priority (self_priority) of the VHT-STA3 106 is 1 and the largest_priority is 1, the ATNAV value of the VHT-STA3 106 becomes 0 according to equation (4). Accordingly, the VHT-STA3 106 sets the ATNAV value to 0 (250) after transmitting the block Ack (block Ack3) (248). The ATNAV value is 0, indicating that all of the VHT-STAs 102, 104, 106 have sent a block Ack.

Since the VHT-STA1 102 alone is allocated antenna resource # 0 for 20 ms, it is not necessary to set the ATNAV value.

As described above, the case in which the VHT-AP 100 transmits data to the plurality of VHT-STAs has been described. Next, a case in which a plurality of VHT-STAs transmit data to the VHT-AP in a wireless communication network in which one or more VHT-STAs and one or more non-VHT-STAs coexist will be described with reference to FIGS. 3 and 4. . Of course, the present invention can also be applied to the case where one VHT-STA transmits data to the VHT-AP. In particular, in the embodiment described with reference to FIG. 4, VHT-STA1 102, VHT-STA2 104, and VHT-STA3 106 transmit data of different sizes to VHT-AP 100. Hereinafter, portions that overlap with those described in FIGS. 1 and 2 will be omitted.

First, the VHT-STAs receive a message from the VHT-AP indicating that there is a non-VHT-STA in the wireless communication network (322). The message received in step 322 may be the same as the message that the VHT-AP notifies the existence of the non-VHT-STA in step 122 of FIG. 1. Therefore, when the VHT-STAs receive a message indicating that a non-VHT-STA exists from the VHT-AP, it can be seen that the method disclosed in the present invention should be used when transmitting data to the VHT-AP. .

As an example, referring to FIG. 4, the VHT-AP 100 may notify 402 that a non-VHT-STA 108 exists in a wireless communication network through a beacon frame. . This is the same as described above in step 202 of FIG. 2. The VHT-STAs 102, 104, 106 know whether a non-VHT-STA 108 exists in a wireless communication network through time sharing information in a beacon frame received from the VHT-AP 100. When the time sharing information is ON, the VHT-STAs 102, 104, and 106 transmit the protection information to the VHT-AP 100 using the time resource distribution method between the guard interval setting and the VHT-STA according to the present invention. It will be recognized that data should be transmitted. That is, by preventing the VHT-STAs 102, 104, 106 and the non-VHT-STAs 108 from simultaneously transmitting or receiving data through time sharing information included in the beacon frame, a waste of resources may occur. Inefficiency can be eliminated.

The VHT-STAs that wish to transmit data to the VHT-AP transmit a message to the VHT-AP, all non-VHT-STAs and other VHT-STAs indicating that they are going to use radio resources (324).

As an example, referring to FIG. 4, the VHT-STAs 102, 104, and 106 transmit a message indicating that the radio resource is to be used for a predetermined period after the DIFS time. VHT PPDU2 and non-VHT PPDU3) (404). As described in FIG. 2, the VHT-STAs 102, 104, 106 are non-VHT PPDUs (non-VHT PPDU1, non-) that all VHT-STAs 102, 104, 106, 110 and all non-VHT-STAs 108 can receive. VHT-PPDU2, non-VHT PPDU3) in the recipient address (RA) field to the VHT-AP (100) address is transmitted. In step 404, the VHT-STAs 102, 104, and 106 may transmit non-VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3) when the NAV value is 0 after DIFS time elapses. When the NAV value is 0, the AP 100 may receive non-VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, and non-VHT PPDU3).

The non-VHT-STAs 108 set their first NAV values as interval field values in the received non-VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3). (406). At this time, the duration field value in each non-VHT PPDU (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3) transmitted by each VHT-STA 102, 104, 106 may be different. This is because each VHT-STA 102, 104, 106 has transmission data of different sizes, and does not know information and resource allocation information of VHT-STAs to transmit data to the VHT-AP 100. In one embodiment, the non-VHT-STAs 108 are the first NAV as the largest value of the interval field values in the received non-VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3). You can set the value. In this case, the first NAV value may not coincide with the guard period 400. The non-VHT-STAs 108 receive the acknowledgment messages Ack1, Ack2, and Ack3 from the VHT-STAs 102, 104, and 106, and then accurately recognize the information about the guard interval 400. Accordingly, the non-VHT-STAs 108 may use the information of the acknowledgment messages Ack1, Ack2, and Ack3 received from the VHT-STAs 102, 104, and 106 to time the guard interval 400 ends. Next, a second NAV (Second NAV) value is set (414). In this way, it is possible to prevent the non-VHT-STAs 108 from obtaining a radio resource while the VHT-AP 100 transmits data to the VHT-STAs 102, 104, 106.

All VHT-STAs receive resource allocation information from the VHT-AP (326).

As an example, referring to FIG. 4, the VHT-AP 100 may receive 404 non-VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3) after RIFS time. In operation 408, a message including resource allocation information for the VHT-STAs 102, 104, and 106 is transmitted in the form of a VHT PPDU. This is the same as described above in step 208 of FIG. 2. In step 208 of FIG. 2, the VHT-AP 100 transmits resource allocation information for the VHT-STAs 102, 104, and 106 to which data is to be transmitted. In step 408 of FIG. Receiving the VHT PPDUs (non-VHT PPDU1, non-VHT PPDU2, non-VHT PPDU3) and recognizing that the VHT-STAs (102, 104, 106) are to transmit data, then allocates resources to the VHT-STAs (102, 104, 106) Send the information. Hereinafter, a case in which the VHT-AP 100 transmits resource allocation information of FIG. 5 to the VHT-STAs 102, 104, 106, and 110 according to an embodiment will be described.

5 shows that the VHT-AP 100 allocates resources to the VHT-STA1 102, the VHT-STA2 104, and the VHT-STA3 106. Accordingly, among the VHT-STAs 102, 102, 104, 106, and 110 that have received the resource allocation information, the VHT-STAs 110 having no resource allocation set the NAV value to the time until the guard interval 400 ends (410). .

The VHT-STAs allocated with the resource transmit an acknowledgment message for the resource allocation information to the VHT-AP (328).

An embodiment will be described with reference to FIG. 4. Among the VHT-STAs 102, 104, 106, and 110, the VHT-STAs 102, 104, and 106 allocated with the resource receive an acknowledgment message (Ack1, Ack2 and Ack3 are transmitted to the VHT-AP 100 (412). As in step 212 of FIG. 2, the VHT-STAs 102, 104, and 106 to which the resource is allocated know what resource is allocated to them through the resource allocation information (FIG. 5), and in response, the acknowledgment message (Ack1, Ack2 and Ack3 are transmitted to the VHT-AP 100 (412).

The VHT-STAs allocated with the resource transmit data to the VHT-AP according to the resource allocation information (330).

As an example, referring to FIG. 4, the resource-allocated VHT-STAs 102, 104, and 106 transmit acknowledgment messages Ack1, Ack2, and Ack3 for resource allocation information (FIG. 5) and RIFS. After the elapse of time, data is transmitted to the VHT-AP 100 according to the resource allocation information (Fig. 5) (418, 422, 432).

Hereinafter, a method in which the VHT-AP 100 and the VHT-STAs 102, 104, and 106 transmit and receive data according to the resource allocation information of FIG. 5 will be described.

Referring to FIG. 5, the VHT-STA2 104 and the VHT-STA3 106 allocated by temporally distributing the same antenna resource # 1 transmit their data using resource allocation information (FIG. 5). Set the previous NAV (hereinafter 'BTNAV') value. The BTNAV value may be set by Equation 3 described above. Referring to Equation 3, each of the VHT-STA2 104 and the VHT-STA3 106 adds their BTNAV values by summing all allocation times of VHT-STAs having a higher priority than their own priority (self_priority). Obtain

Since the priority (self_priority) of the VHT-STA2 104 is 0, the BTNAV value of the VHT-STA2 104 becomes 0 according to equation (3). Accordingly, the VHT-STA2 104 sets the BTNAV value to 0 after the RIFS time elapses (420). Since the BTNAV value is 0 (420), the VHT-STA2 104 transmits data to the VHT-AP 100 through the antenna # 1 (422).

Since the priority (self_priority) of the VHT-STA3 106 is 1, the BTNAV value of the VHT-STA3 106 is 120 ms in the allocation time of the VHT-STA2 104 having a priority of 0 according to Equation (3). Accordingly, the VHT-STA3 106 sets the BTNAV value to 120ms after the RIFS time elapses (428). When the BTNAV value is 0 (430), the VHT-STA3 106 transmits data to the VHT-AP 100 through the antenna # 1 (432).

The VHT-STA1 102 does not need to set the BTNAV value, as described above. Accordingly, the VHT-STA1 102 transmits data to the VHT-AP 100 through antenna # 0 after the RIFS time elapses (418).

In addition, the VHT-STA2 104 and the VHT-STA3 106 using the same antenna resources in time distribution transmit all their data and then wait for all other VHT-STAs to transmit the data.

To implement this, the VHT-STAs 104 and 106 use the resource allocation information (Fig. 5) to set the NAV (hereinafter 'ATNAV') value after transmitting data. The ATNAV value may be set by Equation 4 described above. Referring to Equation 4, each of VHT-STA2 104 and VHT-STA3 106 adds their ATNAV value by summing all allocation times of VHT-STAs having a priority lower than its own priority (self_priority). Obtain

Since the priority (self_priority) of the VHT-STA2 104 is 0 and the largest_priority is 1, the ATNAV value of the VHT-STA2 106 is assigned the VHT-STA3 106 having a priority of 1 according to Equation (4). The time is 80ms. Accordingly, the VHT-STA2 104 sets the ATNAV value to 80 ms after transmitting data (422) (424). If the ATNAV value then becomes 0 (426), it indicates that all of the VHT-STAs 102, 104, 106 have transmitted data.

Since the priority (self_priority) of the VHT-STA3 106 is 1 and the largest_priority is 1, the ATNAV value of the VHT-STA3 106 becomes 0 according to equation (4). Accordingly, the VHT-STA3 106 sets ATNAV value to 0 after transmitting the data (432) (434). The ATNAV value is zero, indicating that all of the VHT-STAs 102, 104, 106 have transmitted data.

Since the VHT-STA1 102 alone is allocated antenna resource # 0 for 20 ms, it is not necessary to set the ATNAV value.

The VHT-STAs that transmit the data receive an acknowledgment message for the data from the VHT-AP (332).

As an example, referring to FIG. 4, the VHT-AP 100 receives data from the VHT-STAs 102, 104, and 106 (416). After the RIFS time elapses, the VHT-AP 100 receives an acknowledgment message for the data from resource allocation information ( And transmits according to FIG. 5).

Among the VHT-STAs 102, 104 and 106, the VHT-STAs 104 and 106 allocated by temporally distributing the same antenna resource are allocated using NAV (hereinafter, 'BRNAV') before receiving their block Ack using resource allocation information (FIG. 5). ') Set the value. The BRNAV value may be set by Equation 1 described above. Referring to Equation 1, each of the VHT-STA2 104 and the VHT-STA3 106 each sums the block Ack allocation times of the VHT-STAs having a higher priority than their own priority (self_priority) to their BRNAV. Find the value.

Since the priority (self_priority) of the VHT-STA2 104 is 0, the BRNAV value of the VHT-STA2 104 becomes 0 according to Equation (1). Accordingly, the VHT-STA2 104 sets the ATNAV value to 0 (426) and sets the BRNAV value to 0 after the RIFS time elapses (440). Since the BRNAV value is 0 (440), VHT-STA2 104 receives a block Ack (Block Ack2) from antenna V1 from VHT-AP 100 (422).

Since the priority (self_priority) of the VHT-STA3 106 is 1, according to Equation 1, 12 ms of the block Ack allocation time of the VHT-STA2 104 having a priority of 0 is increased by the BRNAV value of the VHT-STA3 106. do. Accordingly, the VHT-STA3 106 sets the ATNAV value to 0 (434) and sets the BRNAV value to 12 ms after the RIFS time elapses (448). Then, when the BRNAV value becomes 0 (450), the VHT-STA3 106 receives a block Ack (Block Ack3) from antenna V1 from the VHT-AP 100 (452).

Since the VHT-STA1 102 alone is allocated antenna resource # 0 for 200 ms, it is not necessary to set the BRNAV value. Accordingly, the VHT-STA1 102 transmits data and receives the block Ack (Block Ack1) from the VHT-AP 100 via the antenna # 0 after the RIFS time elapses (438).

In addition, the VHT-STAs 104 and 106 that share and use the same antenna resource in time receive their own block Ack (Block Ack2 and Block Ack3), and then all of the VHT-STAs 102, 104 and 106 receive the block Ack. Wait until you finish it.

To implement this, the VHT-STAs 104 and 106 use the resource allocation information (Fig. 5) to set the NAV (hereinafter 'ARNAV') value after receiving its block Ack. The ARNAV value may be set by Equation 2 described above. Referring to Equation 2, each of the VHT-STA2 104 and the VHT-STA3 106 each sums the block Ack allocation times of the VHT-STAs having a priority lower than their own priority (self_priority) to their ARNAV. Find the value.

Since the priority (self_priority) of the VHT-STA2 104 is 0 and the largest_priority is 1, the ARNAV value of the VHT-STA2 106 is a block of the VHT-STA3 106 having a priority of 1 according to equation (2). Ack allocation time is 8ms. Accordingly, the VHT-STA2 104 sets the ARNAV value to 8ms after receiving the block Ack2 (442) (442). If the ARNAV value is then zero (446), it indicates that all of the VHT-STAs 102, 104, 106 have received a block Ack.

Since the priority (self_priority) of the VHT-STA3 106 is 1 and the largest_priority is 1, the ARNAV value of the VHT-STA3 106 becomes 0 according to equation (2). Accordingly, the VHT-STA3 106 sets the ARNAV value to 0 (454) after receiving the block Ack 452 (452). The ARNAV value is zero, indicating that all of the VHT-STAs 102, 104, 106 have received a block Ack.

Since the VHT-STA1 102 alone is allocated antenna resource # 0 for 20 ms, it is not necessary to set the ARNAV value.

In the present invention, the VHT-AP and the VHT-STA transmit and receive a frame determined according to the data transmission / reception method disclosed in any one of FIGS.

Specifically, the VHT-AP and the VHT-STA determine a frame to be transmitted according to the data transmission / reception method disclosed in the present invention, and encode the frame at which the transmission is determined in a PHY layer (Physical Layer) to transmit through an antenna. .

In addition, the VHT-AP and the VHT-STA decode the frame received through the antenna and perform the following procedure according to the data transmission / reception method disclosed in the present invention.

The method of the present invention as described above may be embodied as a program and stored in a computer-readable recording medium (such as a CD-ROM, a RAM, a ROM, a floppy disk, a hard disk, or a magneto-optical disk). Since this process can be easily implemented by those skilled in the art will not be described in more detail.

The present invention described above is capable of various substitutions, modifications, and changes without departing from the technical spirit of the present invention for those skilled in the art to which the present invention pertains. It is not limited by the drawings.

Claims (1)

A method in which an access point transmits data to a plurality of Very High Throughput (VHT) -stations in a wireless communication network,
Notifying that there is a non-VHT-station in the wireless communication network;
Transmitting a message indicating that data is to be transmitted to the plurality of VHT-stations for non-VHT-stations and VHT-stations existing in the wireless communication network;
Transmitting resource allocation information for the plurality of VHT-stations; And
Transmitting the data to the plurality of VHT-stations according to the resource allocation information.

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