KR100526549B1 - Apparatus and method for data communication using shortened data frame in wireless LAN system - Google Patents

Abstract

The present invention relates to a wireless local area network (W-LAN) system and method for transmitting and receiving data through a data frame, and more particularly, between a DSS-AP and a wireless terminal belonging to the same BSS in a wireless LAN system. A standard data frame of a WLAN by replacing an address field having a fixed length address information with a shortened address field having a shorter address ID value shorter than the standard length address information when transmitting and receiving a data frame. This is to transmit and receive a shorter data frame.

Transmitting and receiving the shortened data frame according to the present invention as described above reduces the radio bandwidth used for the data header, thereby making more use of the radio bandwidth for data communication, so that a large number of users can efficiently use the limited radio resources. Make it available.

In addition, by transmitting and receiving the shortened data frame, it is possible to shorten the transmission time, thereby reducing the probability of collision during wireless medium access, thereby increasing the total number of receiving terminals of the DSS-AP than the conventional method.

Description

Wireless LAN system and method for transmitting and receiving data through shortened data frame {Apparatus and method for data communication using shortened data frame in wireless LAN system}

The present invention relates to a wireless local area network (W-LAN) system and method for transmitting and receiving data through a data frame, and more particularly, to an access point and an arbitrary wireless terminal in a wireless LAN system. The present invention relates to a wireless LAN system and a method for transmitting and receiving data through a shortened data frame.

In general, local area networks (LANs) are networks configured to communicate between terminals for transmission and reception of computers and data in a limited area of several km, and are capable of transmitting information up to 100Mbps. In such a general local area network, the recent wireless LAN is used in places where network connectivity between buildings, telemetry, department store parking lots, renting companies, etc. is difficult to cabling, and the network environment changes frequently when mobile computing is required. There is a trend.

Among these, the MAC (Medium Access Control) protocol of the currently available standard wireless LAN product is IEEE802.11 developed by the IEEE working group. The MAC is a part corresponding to the second layer of the OSI (Open System Interconnection), a data link protocol, which allows the wireless terminal to secure a transmission right in a state where several wireless terminals share the same transmission medium.

With the development of the IEEE802.11 based wireless communication technology described above, the WLAN frenzy started by businesses is rapidly spreading to homes. However, connecting the home to the wireless LAN still requires a lot of effort. Research on how to efficiently provide limited radio resources to a large number of users in local area network (RF) communication is required, and activation of the 2.3 GHz frequency band, which enables wired and wireless integration, has emerged as a very small concern.

FIG. 1 illustrates standard components of a WLAN system proposed in IEEE802.11, which is a MAC standard of the WLAN, and includes a basic service set (hereinafter referred to as BSS) and a distribution system (DS). ), An extended service set (hereinafter referred to as ESS), a distributed system access point (hereinafter referred to as a DSS-AP), and a wireless terminal (Station or STAx). The wireless terminal 10 is a terminal having an IEEE 802.11a / b / g wireless service function, which may include a mobile phone, a PDA, a smart phone, a wireless VoIP phone, and the BSS 30 has one control function. (Coordination Function) or a set of wireless terminals 10 controlled by one DSS-AP 20, and also an arbitrary WLAN service area controlled by the DSS-AP 20. In addition, the DS 40 is a system for generating an ESS by connecting the BSS 30 with local area networks (LANs), which are external networks. The DSS-AP 20 is an access point for interworking the BSS 30 and the DS 40. The DSS-AP 20 is connected to an external network through the DS 40 and the BSS 30. To control.

In order to transmit and receive data between the wireless terminal 10 and the DSS-AP 20, authentication and association should be made through a predetermined process.

2 is a state transition diagram of a process of establishing an authentication and association for transmitting and receiving data between the wireless terminal 10 and the DSS-AP 20. Initially, both the wireless terminal 10 and the DSS-AP 20 are initialized to an unauthenticated / unassociated state (S10), and the DSS-AP 20 is requested by the authentication request of the wireless terminal 10. Is transited to the authenticated / U-associated state (S11). After completing the authentication process, the wireless terminal 10 sends an association request message to the DSS-AP 20, and the DSS-AP 20 responds to the association request message to the wireless terminal 10. A message is sent to the authenticated / associated state (S12) by sending a message), and data transmission and reception are possible. The request and response message for the association procedure includes service supportable information of the wireless terminal 10 and the DSS-AP 20.

3 is a standard frame structure of the service support information (hereinafter, referred to as Capability Information) of the wireless terminal 10 and the DSS-AP 20, and includes an extended service set (ESS) field (F10) and an independent basic service (IBSS). It consists of a Set (F11) field, a F11 (Connection Free) Pollable field (F12), a CF Poll Request field (F13), a Privacy field (F14), and an 11-bit reserved field (F15) that is not currently used. Each field except the Reserved field has a value of On (1) or Off (0) as a flag for supporting any service, and the DSS-AP 20 and the wireless terminal 10 are standard shown in FIG. By exchanging the Capability Information frame of the structure, it is possible to identify mutually supportable services, and the wireless terminal 10 and the DSS-AP 20 transitioned to the authenticated / associated state (S12) are IEEE802.11. Data is transmitted / received through a standard data frame defined in, and communication is performed by specifying a transmission frame type such as Management, Control, Data, etc. in the FC (Frame Control) field in the standard data frame according to the frame to be transmitted.

4 is a structure of the standard FC (Frame Control) field, V (protocol version) (F201), T (type) field (F202), ST (Subtype) field (F203), ToDS (To Distribution System) field ( F204), FromDS (From Distribution System) field (F205), MFrag (More Fragment) field (F206), Re (Retry) field (F207), PMgt (Power Management) field (F208), MData (More Data) field ( F209), a WEP (Wired Equivalent Privacy) field F210, and an O (Order) field F211.

The T field F202 indicates a transport frame type of Management, Control, Data, etc., and a more detailed type is shown in the ST field F203. In addition, the ToDS field F204 is a flag indicating the direction of data, and is in the ON (1) state in the case of the data going from the wireless terminal 10 to the DS 40. Similarly, the FromDS field F205 is also a flag indicating the direction of data, and in the case of data entering the wireless terminal 10 from the DS 40, it is turned on (1).

When the T field F202 of the FC (Frame Control) field F20 is set to a value corresponding to the Data type, the wireless terminal 10 and the AP 20 are connected to the standard data frame shown in FIG. Data will be transmitted to and received from each other.

FIG. 5 shows the standard data frame structure, which is an FC (Frame Control) field (F20), a Duration / ID field (F21), an AD1 (Address 1) field (F22), an AD2 (Address 2) field (F23), and an AD3 ( Address 3) field (F24), SEQ (Sequence) field (F25), AD4 (Address 4) field (F26), FB (Frame Body) field (F27), FCS (Frame Check Sequence) (F28) field .

The ADx fields F22, F23, F24, and F26 correspond to DA (Destination Address), SA (Source Address), and BSSID (Basic Service Set Identification) according to ToDS (F204) and FromDS (F205) flag values of the FC field F20. ), N / A (Not Applicable), RA (Receiving Address), TA (Transmitter Address), etc., and the ADx fields F22, F23, F24, and F26 are 6 bytes each. Since any wireless terminal 10 communicates with the DSS-AP 20 in the same BSS 30, the address of the DSS-AP 20 and the address of the wireless terminal 10 are fixed to mutually agreed values. The contents of the ADx fields F22, F23, F24, and F26 of 24 bytes in total remain unchanged. Using this unchanged 24-byte address field has the following inefficiencies:

1. Since the address field with a lot of overhead is used as it is, the length of the entire frame is long.

2. Since the length of the entire frame is long, the transmission time becomes long.

3. Since the transmission time is long, the collision probability increases when the other terminal accesses the wireless medium.

4. Since the collision probability is increased during the wireless medium access, the frame throughput of the terminal is lowered.

5. Since the collision probability increases during the wireless medium access, the total number of receiving terminals of the DSS-AP is limited.

6. Waste of radio bandwidth occurs due to the use of the header for each frame.

Accordingly, the present invention has been made to solve the above-described problem, and when transmitting and receiving a data frame between the DSS-AP 20 and the wireless terminal 10 belonging to the same BSS (30), the standard length of having a standard address information The address field is replaced with a shortened address field having a length shorter than that of the standard length address field, thereby transmitting and receiving data through a data frame shorter than a standard data frame of the WLAN.

According to an aspect of a wireless LAN system for transmitting and receiving data through a shortened data frame according to the present invention for achieving the above object, in a wireless LAN system consisting of one or more Basic Service Set (BSS) and distribution system (DS) And a DSS-AP interworking the BSS and the DS, and a wireless terminal belonging to the BSS and connected to the DSS-AP through a wireless LAN, wherein the DSS-AP and the wireless terminal are data frames conforming to a wireless LAN standard. Data is transmitted and received to each other by a shortened data frame having a shortened address field shorter than an address field of the data field, and the shortened address field is used for address information to be transmitted to a counterpart according to the WLAN standard between the DSS-AP and the wireless terminal. Corresponding and used to transmit a short address ID for identifying the wireless terminal.

In addition, the DSS-AP is a DSS-AP for providing a DSS in conjunction with the DS, the data transmission and reception unit for receiving data from the wireless terminal, or transmitting data to be sent to the wireless terminal; A data controller which analyzes a type in a data frame header received through the data transceiver and transmits data to a corresponding processing module; A standard mode processor configured to receive and process the WLAN standard data transmitted by the data controller; A shortened mode processor configured to receive and process the shortened data frame transmitted by the data controller, and to generate a shortened address ID for identifying the wireless terminal; And a shortened address ID table for storing the shortened address ID generated by the shortened mode processor and address information to be transmitted to the other party according to the WLAN standard.

In addition, the wireless terminal is a terminal having an IEEE 802.11x wireless service function, and may be a mobile phone, a PDA, a smart phone, a wireless VoIP phone, and receives data from the DSS-AP or data to be sent to the DSS-AP. Data transmitting and receiving unit for transmitting; A data controller which analyzes a type in a data frame header received through the data transceiver and transmits data to a corresponding processing module; A standard mode processor configured to receive and process the WLAN standard data transmitted by the data controller; A shortened mode processor configured to receive and process the shortened data frame transmitted by the data controller; And a short address ID table for storing the short address ID allocated from the DSS-AP and address information to be transmitted to the other party according to the WLAN standard.

On the other hand, according to an aspect of the method for transmitting and receiving data through a shortened data frame in a wireless LAN system according to the present invention, a wireless terminal belonging to any basic service set (BSS) of the wireless LAN system, and the BSS (Basic Service) In a method in which a DSS-AP interworking with a DS (distribution system) to transmit and receive data through a wireless LAN, the wireless terminal uses a shortened address field set shorter than an address field of a data frame according to a wireless LAN standard. Requesting the DSS-AP for a short mode setting for transmitting and receiving data to and from the DSS-AP using a shortened data frame; Generating, by the DSS-AP receiving the request, a short address ID for identifying the wireless terminal, and transmitting a response message including the short address ID to the wireless terminal; The wireless terminal receiving the response message stores address information to be transmitted to the DSS-AP according to the wireless LAN standard and the short address ID included in the response message, and stores a confirmation message for the DSS. Setting a setting mode of the wireless terminal to the reduced mode after transmitting to the AP; After the DSS-AP receives the confirmation message from the wireless terminal, the DSS-AP corresponds to the short address ID and address information to be transmitted to the wireless terminal according to the wireless LAN standard. It may include setting a setting mode for the shortened mode.

The above configuration and features will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings for a WLAN system and a method for transmitting and receiving data through the shortened data frame as described above.

6 is a diagram illustrating a WLAN network connection configuration for transmitting and receiving data through a shortened data frame according to the present invention.

As shown in FIG. 6, the wireless LAN system according to the present invention includes a wireless terminal 100 supporting shortened data service, a DSS-AP 200 supporting shortened data service, and a set of the wireless terminal 100. The BSS 30 and the distributed BSS 30 may be configured as a distributed system 40 for interworking with local area networks (LANs).

The wireless terminal 100 receives the data from the DSS-AP (200) belonging to the same BSS (30) or data transmission and reception unit 101 for transmitting data to be sent to the DSS-AP (200), and the data transmission and reception unit A data control unit 102 for analyzing the type in the data frame header received through the 101 and transmitting data to the processing module, and a standard mode processing unit for receiving and processing data of the wireless LAN standard type from the data control unit 102. 105, a shortcut mode processing unit 103 for receiving and processing data in the shortened data frame from the data control unit 102, and a shortcut address ID allocated from the DSS-AP 200 (hereinafter, 'CAID'). It may include a Compressed Association Identifier) and a shortened address ID table (hereinafter referred to as 'CAID table' 104) to correspond to and store the address information to be transmitted to the other party according to the WLAN standard. .

In addition, the DSS-AP 200 illustrated in FIG. 6 is an AP interworking the BSS 30 and the DS 40, and receives data from any wireless terminal 100 belonging to the same BSS 30. A data control unit for transmitting data to be transmitted to the wireless terminal 100 and a data control unit for analyzing data types in the data frame header received through the data transmission and reception unit 201 and transmitting the data to the corresponding processing module. 202, and a standard mode processing unit 205 for receiving and processing data of a wireless LAN standard type from the data control unit 202, and receiving and processing a shortened data frame from the data control unit 202. The short mode processing unit 203 for generating a CAID for identifying the ID and the CAID generated by the short mode processing unit 203 correspond to and store address information to be transmitted to the wireless terminal 100 according to the wireless LAN standard. CAID may include a table 204.

That is, the DSS-AP 200 stores address information of the wireless terminal 100 that has established a short mode connection in the CAID table 204 to transmit and receive data through the short data frame. 100 stores the address information of the DSS-AP 200 which has established a short mode connection with itself in the CAID table 104.

FIG. 7 illustrates a state transition diagram of a process for establishing an authentication and association for transmitting and receiving data between the wireless terminal 100 and the DSS-AP 200 including the short mode connection process. In the state transition diagram according to the present invention, in the state transition diagram of the prior art illustrated in FIG. 2, the 'authentication / shortened mode connection state' (S13) is further added, and the first wireless terminal 100 and the DSS-AP ( 200 is all initialized to Unauthenticated / Unassociated (S10), and the authentication / disconnected state through the process of the DSS-AP 200 responds to the authentication request of the wireless terminal 100 ( Authenticated / Unassociated) (S11). After completing the authentication process, the wireless terminal 100 sends an association request message to the DSS-AP 200, and the DSS-AP 200 responds to the association request message to the wireless terminal 100. By sending a (Response) message, the system transitions to the authenticated / associated state (S12), and mutual data transmission and reception are possible. The request and response message for the association procedure includes a service supportability information field (hereinafter, referred to as a 'capability information field') of the wireless terminal 100 and the DSS-AP 200. The wireless terminal In the Capability Information field interchanged between the 100 and the DSS-AP 200, when both the flags for the 'shortening mode support' are set to ON (i.e., supportable), mutual data is transmitted and received through the shortened data frame. To this end, the wireless terminal 100 and the DSS-AP 200 exchanges a mutual short mode access (CA) request message and a response message thereto, thereby providing an 'authentication / shortened mode access' state ( S13).

8 is a Capability Information field structure according to the present invention including a flag for 'shorten mode support'. The flag CA for 'shortening mode support' uses one bit F151 of an unused 11-bit reserved field F15 in the conventional standard Capability Information frame structure shown in FIG. . The Capability Information field of the Association Response message sent from the DSS-AP 200 to the wireless terminal 100 is Capability Information of the Association Request message sent from the wireless terminal 100 to the DSS-AP 200. Has the same structure as

In the Capability Information field exchanged between the wireless terminal 100 and the DSS-AP 200, the wireless terminal 100 confirming that both of the flags for 'shortening mode support' are set to ON (that is, supportable). After the DSS-AP 200 undergoes an 'authentication / shortened mode access' procedure (S13), the DSS-AP 200 transmits and receives mutual data through a shortened data frame.

9 shows the format of the shortened data frame.

The FC field F20 uses the conventional FC field shown in FIG. 4 as it is, except that the values of the T (Type) field F202 and the ST (SubType) field F203 become predetermined values corresponding to the short mode. . The CAID field F99 replaces the entire AD1 (F22), AD2 (F23), AD3 (F24), AD4 (F26) fields of 24 bytes in the conventional standard data frame shown in FIG. Since the length of the field F99 is 2 bytes, the data frame length is shortened by 22 bytes. Therefore, the Duration / ID field F21 uses a value obtained by decreasing the time corresponding to 22 bytes. The remaining SEQ (Sequence) field F25, the FB (FrameBody) field F27, and the FCS (Frame Check Sequence) field F28 are all used in the same manner as the conventional field shown in FIG. The Compressed Association Identifier (CAID) refers to a shortened address ID of two bytes randomly generated by the DSS-AP 200 and the wireless terminal 100 to establish the 'authentication / shortened mode access' procedure (S13). ) The DSS-AP 200 receiving the shortened mode access (hereinafter referred to as CA) request message sent randomly generates the CAID, and includes the CAID in the CA response message to the wireless terminal 100. Will be sent.

10 illustrates a CA request process of the wireless terminal 100. After supporting the short mode and transmitting the CA request message to the DSS-AP 200 confirming that the wireless terminal 100 in the authentication / connection state (S12) also supports the short mode (S101), Wait for the response message. It is determined whether a CA response message is received within a predetermined timeout time (S102). If the timeout time is exceeded, the DSS-AP 200 requests retransmission. In this case, when the number of retransmission requests exceeds a predetermined maximum number, the retransmission request is transmitted in a standard mode transmitted through a standard data frame instead of a short mode transmitted through a short data frame. When the wireless terminal 100 receives the CA response message from the DSS-AP 200, the CAID table is mapped by mapping the CAID included in the response message with the original 24-byte long DSS-AP 200 address. After recording in S104 (S103), a confirmation message is transmitted to the DSS-AP 200 (S104), and then a setting mode is set to a reduced mode in order to transmit and receive data through the shortened data frame. (S105).

11 shows a process in which the DSS-AP 200 receiving the CA request message responds. Receiving a CA request message from the wireless terminal 100 (S201), the DSS-AP generates a CAID through a predetermined method (S202). The generated CAID is included in the CA response message and transmitted to the wireless terminal 100 (S203). The wireless terminal 100 waits for a confirmation message. It is determined whether a confirmation message has been received within a predetermined timeout time (S204). If the timeout time is exceeded, the wireless terminal 100 requests retransmission. In this case, when the number of retransmission requests exceeds a predetermined maximum number, the retransmission request is transmitted in a standard mode that is transmitted through a conventional standard data frame instead of a shortened mode. When the DSS-AP 200 receives a confirmation message from the wireless terminal 100, the DSS-AP 200 records the generated CAID in the CAID table 204 (S205), and then transmits and receives data through a shortened data frame. In order to do this, the setting mode is set to the short mode (S206).

12 shows how the DSS-AP 200 generates the CAID. First, a random number is generated by a general random function (S2021). Then, it is determined whether the generated number is odd (S2022). If it is odd, it is left as it is. If it is even, it is made odd by adding 1 (S2023). For this number, check whether it is duplicated with the existing CAID (S2024). If it is duplicated, generate a random number again (S2021), and if there is no duplicate CAID, output the generated number as a CAID (S2025). It is a process.

The reason for the unconditional odd CAID in the process is to distinguish the CAID when sending data from the DSS-AP 200 to the wireless terminal 100 and the DSS-AP 200 when sending data from the wireless terminal 100. To do that. The odd CAID is a CAID used to transmit data from the DSS-AP 200 to the wireless terminal 100 and is a value stored in the CAID table 204 of the DSS-AP 200. At this time, the 24-byte standard address field of the wireless terminal 100 is also mapped with the CAID and stored together. The even CAID is a CAID used when sending data from the wireless terminal 100 to the DSS-AP 200, which is CAID because 1 is added to CAID stored in the CAID table 204 of the DSS-AP 200. The table 204 does not need to be stored further. Accordingly, the size of the CAID tables 104 and 204 of the DSS-AP 200 and the wireless terminal 100 can be reduced.

The generated two-byte CAID is fixed in data transmission and reception between the wireless terminal 100 and the DSS-AP 200, so that a 24-byte address field (ADD1, ADD2, ADD3, ADD4) in a conventional standard data frame which does not change. ), So that the data frame length is reduced by 22 bytes to efficiently use the wireless bandwidth. The shortened data frame is made through the following process.

13 is a flowchart illustrating a process in which the wireless terminal 100 or the DSS-AP 200 processes a standard data frame into the shortened data frame. First, it is determined whether the received frame is a data frame exchanged with the DSS-AP (S501). If the received frame is not a data frame exchanged with the DSS-AP, the frame is processed without changing the frame format (S502). In the case of a data frame of "data" type having an address field (ADD1, ADD2, ADD3, ADD4) of bytes, the own CAID table 104 or 204 is searched for the value of the address field of 24 bytes. It is determined whether there is a CAID mapped (S503). If there is no CAID mapped, the process is processed in standard mode without changing the frame format (S502). If there is a CAID mapped, the ToID value is added to the CAID field in the data frame (S504). The address fields ADD1, ADD2, ADD3, and ADD4 are deleted (S505), and the Type field and the Sub Type field of the FC field are set to values corresponding to the shortened data frame. The reason why the ToID (F204) value is added to the CAID is to transmit the data frame to the DSS-AP 200 using an even number because the CAID found in the CAID table 104 is odd in the wireless terminal 100.

FIG. 14 is a flowchart opposite to that of FIG. 13, in which the wireless terminal 100 or the DSS-AP 200 processes a short data frame as a standard data frame. First, it is determined whether the Type (F202) and Subtype (F203) field values of the FC (F20) field of the received data frame are predetermined values corresponding to the shortened mode (S601). The frame is processed in a standard mode method, which is a method of processing a data frame having address information of a conventional standard length (S607). If the Type (F202) and Subtype (F203) field values of the FC (F20) field of the received data frame correspond to the short mode, the CAID value included in the CAID (F99) field of the received data frame is set to ToDS (). F204) After decreasing the value of the flag (S602), the CAID value is found in the CAID table (S603). In this case, the ToDS (F204) flag is 1 when the wireless terminal 100 transmits a data frame to the DSS-AP 200, and when the wireless terminal 100 receives the data frame from the DSS-AP 200. It has a value of zero. The reason why the CAID value included in the CAID (F99) field of the data frame received in step S602 is reduced by the value of the ToDS (F204) flag. In the case of the DSS-AP 200, the CAID value of the received data frame is Since the CAID values stored in the CAID table 204 are all odd numbers, the CAIDs for the corresponding wireless terminal 100 are found by using the stored odd CAIDs. If the CAID of the data frame received in step S602 is an even number, the wireless terminal 100 means a data frame received from the DSS-AP 200, and according to the order specified in the WLAN standard, the contents of the stored address field Processing is performed as a standard mode frame using the order of AD1 (DA), AD2 (BSSID), AD3 (SA), and AD4 (N / A) as it is (S605). On the contrary, if the CAID of the data frame received in step S602 is an even number, the DSS-AP 200 means a data frame received from the wireless terminal 100 and stored according to the order specified in the wireless LAN standard. The contents of the address field are changed in the order of AD2 (BSSID), AD3 (SA), AD1 (DA), and AD4 (N / A) and processed as a standard mode frame (S606).

The DSS-AP 200 and the wireless terminal 100 that transmit / receive data in the short mode mode, cancel the short mode setting, and then transmit and receive data through a data frame including standard length address information. To do this, reset to standard mode through the following signal procedure.

FIG. 15 illustrates a process of requesting release of an address field shortening by the DSS-AP 200 or the wireless terminal 100 during a signal procedure for releasing the shortened mode for using a shortened data frame according to the present invention. . After transmitting the short mode release request from the DSS-AP 200 or the wireless terminal 100 (S301), it is determined whether a response to the short mode release request of the other party is received within a predetermined timeout time (S302). If the response is not received within the predetermined timeout period, the short mode release request is retransmitted within a range not exceeding the maximum number of retransmissions (S305, 306). In this case, the player gives up the other party's response and proceeds to release the short mode. On the other hand, when a response is received within a predetermined timeout time, the CAID table 104 or 204 deletes the CAID included in the short mode release response message and the address information of the standard length stored in correspondence with the CAID. S303), and reset to the standard mode (S304).

FIG. 16 illustrates a case where the DSS-AP 200 and the wireless terminal 100 are requested to release an address field from the signal procedure for releasing the reduced mode for using the reduced data frame according to the present invention. When the DSS-AP 200 or the wireless terminal 100 receives the short mode release request (S401), the DSS-AP 200 or the wireless terminal 100 transmits a response message to the transmitter in response to the short mode release request (S402). In addition, the CAID included in the short mode release request message is found in its CAID table 104 or 204, and the CAID and the address information of the standard length stored in correspondence with the CAID are deleted (S403). Reset (S404).

Although the above has been described with reference to a preferred embodiment of the present invention, those of ordinary skill in the art various modifications of the present invention without departing from the spirit and scope of the present invention described in the claims below And can be changed.

Transmitting and receiving the shortened data frame according to the present invention as described above reduces the radio bandwidth used for the data header, thereby making more use of the radio bandwidth for data communication, so that a large number of users can efficiently use the limited radio resources. Make it available. If the wireless terminal 100 is a voice terminal and the length of the MAC Protocol Data Unit (MPDU) is 100 bytes, the conventional method without using the address field shortening is 168 bytes in length of the physical layer transmission frame. On the other hand, the method of using the address field shortening is 146 bytes in which the length of the transport frame of the physical layer is reduced by 22 bytes. The length of the transmission frame is the transmission time, resulting in a 7% improvement in the use of the radio link.

In addition, by transmitting and receiving the shortened data frame, it is possible to shorten the transmission time, thereby reducing the probability of collision during wireless medium access, thereby increasing the total number of receiving terminals of the DSS-AP than the conventional method.

1 is a diagram showing a conventional standard wireless LAN network connection configuration.

2 is a state transition diagram of a conventional DSS-AP and a wireless terminal (STAx).

3 is a diagram illustrating a standard frame structure of conventional service supportable information.

4 is a diagram illustrating a standard structure of a conventional frame control field.

5 is a diagram illustrating a conventional WLAN standard data frame standard structure.

6 is a diagram illustrating a WLAN network connection configuration for transmitting and receiving data through a shortened data frame according to the present invention.

7 is a state transition diagram of the DSS-AP 200 and the wireless terminal 100 according to the present invention.

8 is a view showing a service support information (Capability Information) frame structure sent from the wireless terminal to the DSS-AP in accordance with the present invention.

9 is a diagram illustrating a shortened data frame structure transmitted and received by a wireless terminal and a DSS-AP having a short mode access (CA) according to the present invention.

10 is a diagram illustrating a CA signal procedure of the STAx for using a shortened data frame according to the present invention.

11 is a diagram illustrating a CA signal procedure of a DSS-AP for using a shortened data frame according to the present invention.

12 is a diagram illustrating a short address ID generation process of a DSS-AP according to the present invention.

13 illustrates a process of processing a standard data frame into a shortened data frame according to the present invention.

14 is a diagram illustrating a process of processing a shortened data frame into a standard data frame according to the present invention.

FIG. 15 is a diagram illustrating a process of requesting address field shortening release from a DSS-AP and STAx during a signal procedure for releasing a short mode for using a shortened data frame according to the present invention; FIG.

16 is a diagram illustrating a process when a DSS-AP and an STAx receive an address field shortening release request during a signal procedure for releasing a shortened mode for using a shortened data frame according to the present invention.

Explanation of symbols on the main parts of the drawings

10: conventional wireless terminal (STAx)

20: conventional DSS-AP

30: BSS (Basic Service Set)

40: DS (Distribution System)

100: wireless terminal (STAx) according to the present invention

200: DSS-AP according to the present invention

Claims (15)

It provides an arbitrary wireless LAN service area, an access point connected to an external network through a specific interface, and one or more wireless terminals belonging to the wireless LAN service area and connected to the access point and a wireless LAN to transmit and receive data with each other. In a wireless LAN system, The access point is a standard mode for transmitting and receiving data with the wireless terminal through a standard data frame having an address field including an originating address, a receiving address, and the WLAN service area identifier, and shorter than the address field in the standard data frame. It supports both the short mode for transmitting and receiving data with the wireless terminal through a short data frame having a short address field of length, The wireless terminal system supports both the standard mode for transmitting and receiving data with the access point through the standard data frame, and the short mode for transmitting and receiving data with the access point through the shortened data frame. The method of claim 1, The access point is a wireless LAN system, characterized in that the DSS-AP (Distribution System Service-Access Point). The method of claim 1, The wireless service area is a wireless LAN system, characterized in that the Basic Service Set (BSS). The method of claim 1, And the short address field corresponds to address information included in the address field of the standard data frame and includes a short address identifier (identifier) value for identifying the wireless terminal. The method of claim 1, The shortened data frame is A frame control field including the type of the shortened data frame, the protocol version used, and a plurality of control flags; A duration / id field including an estimated transmission time of the shortened data frame; A shortcut address ID field corresponding to address information included in the address field of the standard data frame and including a shortcut address ID value identifying the wireless terminal; An SQ (Sequence) field used for loss detection of the shortened data frame, A frame body (FB) field containing user data to be actually transmitted, Wireless LAN system comprising a frame check sequence (FCS) field used for error control. The method of claim 1, The access point is A data transmitting / receiving unit which receives data from the wireless terminal or transmits data to the wireless terminal; A data controller which analyzes a type in a data frame header received through the data transceiver and transmits data to a corresponding processing module; A standard mode processor configured to process the standard data frame transmitted by the data controller; A shortened mode processor configured to process the shortened data frame transmitted by the data controller, and generate a shortened address identifier (ID) corresponding to address information included in an address field of the standard data frame and identifying the wireless terminal; And a shortened address ID table for storing the shortened address ID generated by the shortened mode processor and address information included in the address field of the standard data frame. The method of claim 1, The wireless terminal is A data transmission / reception unit for receiving data from the access point or transmitting data to the access point; A data controller which analyzes a type in a data frame header received through the data transceiver and transmits data to a corresponding processing module; A standard mode processor configured to process the standard data frame transmitted by the data controller; A shortened mode processor configured to process the shortened data frame transmitted by the data controller; And a shortcut address ID table for storing address information included in the address field of the standard data frame and a shortcut address ID for identifying the wireless terminal allocated from the access point. LAN system. A method for providing an arbitrary WLAN service area, and access point connected to an external network through a specific interface, and at least one wireless terminal belonging to the WLAN service area and connected to the access point and the WLAN by mutually transmitting and receiving data. In Transmitting / receiving data through a shortened data frame having a shortened address field having a length shorter than that of the standard data frame, rather than a standard data frame having an address field including a source address, a destination address, and the WLAN service area identifier. Checking, by the wireless terminal and the access point, whether or not a short mode is supported; After confirming that the wireless terminal and the access point support the reduced mode, requesting, by the wireless terminal, to set the reduced mode to the access point; The access point receiving the request corresponds to the address information included in the address field of the standard data frame, generates a short address ID identifying the wireless terminal, and then sends a response message to the wireless terminal. Transmitting; The wireless terminal receiving the response message stores address information included in the address field in the standard data frame to be transmitted to the access point and the short address ID included in the response message, and confirms the message. Setting a setting mode of the wireless terminal to the reduced mode after transmitting a message to the access point; After the access point receives the confirmation message from the wireless terminal, the access point stores the short address ID and the address information included in the address field of the standard data frame together, and the wireless terminal of the access point for the wireless terminal. And setting a setting mode for the shortened mode. The method of claim 8, The shortened data frame is A frame control field including the type of the shortened data frame, the protocol version used, and a plurality of control flags; A duration / id field including an estimated transmission time of the shortened data frame; A shortened address ID field corresponding to address information included in the address field of the standard data frame and including a shortened address ID identifying the wireless terminal; An SQ (Sequence) field used for loss detection of the shortened data frame; A frame body (FB) field containing user data to be actually transmitted, A method of transmitting / receiving data including a frame check sequence (FCS) field used for error control. The method of claim 8, The shortening mode support confirmation of the access point and the wireless terminal, In the Capability Information packet of the access point received by the wireless terminal from the access point, and the Capability Information packet of the wireless terminal received by the access point from the wireless terminal, Data transmission and reception method characterized in that it is confirmed through the flag value of the promised specific location. The method of claim 8, In the wireless terminal in which the setting mode of the wireless terminal is set to the short mode, When canceling the short mode, Sending a shortened mode release request message to the access point; Receiving a response message for the request message from the access point; Deleting a short address ID of the access point and address information of the standard data frame corresponding to the short address ID from the short address ID table; And setting a setting mode of the wireless terminal to a standard mode for transmitting and receiving data with the access point through the standard data frame. The method of claim 8, In the wireless terminal in which the setting mode of the wireless terminal is set to the reduced mode, When a release request message for the reduced mode is received from the access point, Sending a response message to the access point in response to the release request message for the reduced mode; Deleting the short address ID of the access point and the address information of the standard data frame corresponding to the short address ID from the short address ID table; And setting a setting mode of the wireless terminal to a standard mode for transmitting and receiving data with the access point through the standard data frame. The method of claim 8, The short address ID generated by the access point is Generating a random random number; A second step of checking whether the random number is an odd number; A third step of making the number odd by adding 1 if the random number is not odd; A fourth step of determining whether the odd random number overlaps with an existing short address ID; A fifth step of outputting the random number if the random number overlaps with the existing short address ID as a result of the determination; and outputting the random number if the random number does not overlap with the existing short address ID as a result of the determination Data transmission and reception method characterized in that it is generated through. The method of claim 8, In the access point in which a setting mode for the wireless terminal of the access point is set to the reduced mode; When canceling the short mode, Transmitting a short mode release request message to the wireless terminal; Receiving a response message to the request message from the wireless terminal; Deleting the short address ID of the wireless terminal and address information of the standard data frame corresponding to the short address ID from the short address ID table; And setting a setting mode for the wireless terminal of the access point to a standard mode for transmitting and receiving data with the access point through the standard data frame. The method of claim 8, In the access point in which the setting mode for the wireless terminal of the access point is set to the reduced mode, When receiving a message from the wireless terminal requesting the release for the reduced mode, Sending a response message to the wireless terminal in response to the request message; Deleting the short address ID of the wireless terminal and the address information of the standard length corresponding to the short address ID from the short address ID table; And setting a setting mode for the wireless terminal of the access point to a standard mode for transmitting and receiving data through a data frame having the standard length address information.