KR20180049489A - Method for connecting to access point in wlan network - Google Patents

Abstract

Disclosed are an access point connecting method and a wireless terminal in a wireless LAN network based on a dynamic CCAT value. The disclosed access point connecting method includes the steps of: adjusting a CCAT value and estimating the number of hidden nodes for a first access point and an interference component for a second access point; calculating a throughput for the first access point by using the number of hidden nodes and the interference component; and determining whether to connect to the first access point by using the throughput. Accordingly, the present invention can more quickly receive a service with high quality.

Description

[0001] METHOD FOR CONNECTING TO ACCESS POINT IN WLAN NETWORK [0002]

The present invention relates to an access point access method in a wireless LAN network, and more particularly, to a method of access point access based on a dynamic CCAT value.

With the widespread use of IEEE 802.11 wireless LAN devices, wireless devices can be used anytime, anywhere. In order to use services such as the Internet as a wireless LAN, each wireless terminal must select an appropriate access point (AP). The selection of such an appropriate AP plays a decisive role in the performance of the system, including throughput, quality of service (QoS), etc. However, the 802.11 standard does not provide detailed criteria for AP selection.

Various studies have been made to improve the proper AP selection method. The simplest approach is based on Received Signal Strength Indication (RSSI) measurements. When the wireless terminal enters the service area of the WLAN or detects degradation on the current link, the wireless terminal scans each candidate channel and estimates the RSSI of the received frames from the available access points. The wireless terminal then selects the access point with the strongest RSSI, in order to access a high quality channel with a high transmission rate.

Meanwhile, in the wireless LAN communication, in order to prevent a collision in data transmission of wireless terminals, a CCA (Clear Channel Assessment) step is performed before a frame transmission is started to detect whether or not a channel is used. In a CCA step, when a preamble of a header part of a transmitted / received frame is detected, the wireless terminal compares the preamble signal strength and a clear channel assessment threshold (CCAT) value to determine whether to use the channel.

Recently, research is underway to increase network efficiency by dynamically adjusting CCAT.

Korean Patent Laid-Open Publication No. 2016-0084291 is a related prior art.

The present invention is intended to provide a method of access point access in a wireless local area network (WLAN) that enables a wireless terminal to access an access point exhibiting higher throughput performance based on a dynamic CCAT value.

According to an embodiment of the present invention, there is provided a method for adjusting a CCAT value, comprising: estimating a number of hidden nodes for a first access point and an interference component for a second access point; Calculating a throughput for the first access point using the number of hidden nodes and the interference component; And determining whether to connect to the first access point by using the throughput.

According to another aspect of the present invention, there is provided a method for estimating interference between a first access point and a second access point, the method comprising: estimating a number of hidden nodes for a first access point and an interference component for a second access point using a predetermined CCAT value; Calculating a throughput for the first access point using the number of hidden nodes and the interference component; Determining a CCAT value within which the throughput is maximized within a predetermined CCAT value; And accessing the first access point using a CCAT value with the maximum throughput when the throughput for the first access point is at a maximum during throughput for an access point around the wireless terminal, A method for access point access of a wireless terminal in a network is provided.

According to another aspect of the present invention, there is provided an information communication system including an information receiver for receiving a beacon frame from first and second access points; An information estimator for adjusting the CCAT value and estimating the number of hidden nodes for the first access point and the interference component for the second access point; A throughput calculation unit for calculating a throughput for the first access point using the number of hidden nodes and the interference component; And a connection determining unit for determining whether to access the first access point using the throughput.

According to the present invention, the wireless terminal can dynamically adjust the CCAT value and estimate the access point providing the maximum throughput and access the access point providing the maximum throughput using the CCAT value when the maximum throughput is estimated , It is possible to provide a faster and higher quality service.

1 is a view for explaining a wireless terminal in a wireless LAN network according to an embodiment of the present invention.
2 is a flowchart illustrating a method of access point access to a wireless terminal in a wireless LAN network according to an embodiment of the present invention.
3 illustrates a wireless LAN network for explaining an access point access method according to the present invention.
4 is a flowchart illustrating a method of access point connection of a wireless terminal in a wireless LAN network according to a specific embodiment of the present invention.
5 is a diagram illustrating a scenario for simulating an access point connection method according to the present invention.
Figs. 6 to 9 are diagrams for explaining simulation results according to the scenario of Fig. 5. Fig.

While the invention is susceptible to various modifications and alternative forms, specific embodiments thereof are shown by way of example in the drawings and will herein be described in detail. It should be understood, however, that the invention is not intended to be limited to the particular embodiments, but includes all modifications, equivalents, and alternatives falling within the spirit and scope of the invention. Like reference numerals are used for like elements in describing each drawing.

The present invention relates to a method for estimating a throughput of an access point by adjusting a CCAT value for an access point around a wireless terminal to which the wireless terminal is connectable and determining an access point to be connected based on the estimated throughput .

The channel occupancy frequency of the wireless terminal and the carrier sensing range are changed according to the CCAT value, so that the throughput is also different. The wireless terminal according to the present invention uses the CCAT value when the maximum throughput is estimated and the maximum throughput is estimated So that a faster and higher quality service can be provided. To estimate the throughput of the access point, the wireless terminal dynamically changes the CCAT value and estimates the throughput for each CCAT value.

The present invention uses the number of hidden nodes and the interference component of a wireless terminal peripheral access point to estimate the throughput according to the CCAT value and will be described in detail below with reference to the accompanying drawings .

1 is a view for explaining a wireless terminal in a wireless LAN network according to an embodiment of the present invention.

In FIG. 1, there is shown a case where there are first and second access points connectable to a wireless terminal around a wireless terminal, and the number of access points around the wireless terminal may vary according to the embodiment. The wireless terminal can detect a neighboring access point through a scan and a beacon reception process.

Referring to FIG. 1, a wireless terminal 100 according to the present invention includes an information receiving unit 101, an information estimating unit 102, a throughput calculating unit 103, and a connection determining unit 104.

The information receiving unit 101 receives a beacon frame from the first and second access points 110 and 120. The beacon frame includes information on the number of nodes connected to the first and second access points 110 and 120, channel usage, and the like.

The information estimator 102 adjusts the CCAT value and estimates the number of hidden nodes for the first access point 110 and the interference component for the second access point 120. [ As described above, depending on the CCAT value, the CCAT value is adjusted and the information is estimated so that the throughput can be varied and the wireless terminal 100 can access the access point providing the maximum throughput.

The information estimator 102 estimates the number of hidden nodes for the first access point 110 to estimate the throughput and since the second access point 120 that is not is an interference to the wireless terminal 100, And estimates the interference component for the second access point 120. [ Conversely, when the second access point 120 becomes a throughput estimation target, the information estimator 102 adjusts the CCAT value and estimates the number of hidden nodes for the second access point 120, 0.0 > 110 < / RTI >

Although not shown in the figure, the information estimating unit 101 may more specifically include a hidden node estimating unit and an interference component estimating unit.

The hidden node estimator uses the hidden area of the first access point 110 and the number of nodes connected to the first access point 110 with respect to the wireless terminal 100 according to the CCAT value, Estimate the number of hidden nodes. The hidden area is an area where a node that may cause a collision occurs beyond the range of carrier sensing (CS) of the wireless terminal 100. The hidden area is a region where the first access point 110), the number of hidden nodes is estimated for throughput calculation.

The interference component estimating unit estimates the second access point in the interference area using the interference area of the second access point 120 and the channel usage amount of the second access point 120 for the wireless terminal 100 according to the CCAT value And estimates an interference component indicating the channel usage amount of the point 120. [ The interference region is an area in which the coverage of the second access point 120 and the carrier sensing range of the wireless terminal 100 overlap and when the first and second access points 110 and 123 use the same channel, An interference component is reflected in the throughput calculation because the access point 120 may interfere with the wireless terminal 100 and consequently the throughput of the first access point 110 to be connected may decrease in the wireless terminal 100. [

The throughput calculation unit 103 calculates the throughput for the first access point 110 using the estimated number of hidden nodes and interference components. The throughput for the second access point 120 is also calculated. The throughput for the access point is inversely proportional to the number of hidden nodes and the size of the interference component, and the number of hidden nodes and the size of the interference component may vary depending on the CCAT value.

The connection determining unit 104 determines whether to connect to the first access point 110 using the throughput. In one embodiment, the connection determination unit 104 may determine an access point for a maximum throughput among the throughputs calculated for the first and second access points 110 and 120 as a connection target.

The wireless terminal 100 connects to the first access point 110 based on the CCAT value used when the throughput is at a maximum when the throughput for the first access point 110 is maximum.

As a result, according to the present invention, the wireless terminal can dynamically adjust the CCAT value and estimate the access point providing the maximum throughput, and access the access point providing the maximum throughput using the CCAT value when the maximum throughput is estimated It is possible to provide a faster and better quality service.

FIG. 2 is a flowchart illustrating a method of connecting an access point of a wireless terminal in a wireless LAN network according to an embodiment of the present invention. FIG. 3 illustrates a wireless LAN network for explaining a method of connecting an access point according to the present invention. In Fig. 3, a triangle represents an access point, and a circle represents a wireless terminal.

The wireless terminal according to the present invention adjusts the CCAT value, estimates the number of hidden nodes for the first access point and the interference component for the second access point (S210). The wireless terminal adjusts the CCAT value by a predetermined value within a predetermined range, and estimates the number of hidden nodes and the interference component.

First, the wireless terminal 100 calculates the hidden area 311 of the first access point 110 for the wireless terminal 100 according to the CCAT value, and calculates the hidden area 311 of the hidden area 311 and the first access point 110, The number of hidden nodes included in the hidden area 311 is estimated by using the number of nodes (wireless terminals) connected to the hidden area 311. [

 The wireless terminal 100 may calculate the hidden area 311 (H) as shown in Equation (1).

Where d is the distance between the wireless terminal 100 and the first access point 110 and I is the distance between the CS range 300 of the wireless terminal 100 and the coverage 310 of the first access point 110 Represents the distance to the first access point 110. And R represents the radius of the CS range 300 of the wireless terminal 100.

In this case, d, I, and R can be calculated as Equation (2) as an embodiment.

는 path loss exponent를 나타낸다. 그리고 P₀는 무선 단말(100)과 제1액세스 포인트(110) 사이의 거리가 1m일 때의 RSSI 값을 나타낸다. 무선 단말(100)의 CS 범위(300)는 CCAT 값(P_c)에 따라 달리지며, CCAT 값이 작을수록 CS 범위(300)는 커질 수 있다.Where r _i is the RSSI value of the first access point 110 measured by the wireless terminal 100 and θ is the minimum RSSI value for the wireless terminal 100 to transmit data to and receiving data from the first access point 110, _c is the CCAT value of the wireless terminal 100,

Represents the path loss exponent. And P ₀ represents an RSSI value when the distance between the wireless terminal 100 and the first access point 110 is 1 m. The CS range 300 of the wireless terminal 100 may vary according to the CCAT value P _c , and the smaller the CCAT value, the larger the CS range 300.

Finally, the wireless terminal 100 can estimate the number (n _h ) of hidden nodes included in the hidden area 311 using Equation (3). The number of hidden nodes included in the hidden area 311 may be proportional to the size of the hidden area 311 and the number of nodes connected to the first access point 110. [

Here, n _i represents the number of nodes connected to the first access point 110.

The wireless terminal 100 then calculates the interference region 321 of the second access point 120 for the wireless terminal 100 according to the CCAT value and determines the interference region 321 of the interference point 321 and the second access point 120, It is possible to estimate an interference component indicating the channel usage amount of the second access point 120 in the interference region 321 by using the channel usage amount of the second access point 120. [

The wireless terminal 100 may calculate the interference region 321 (C _j ) as shown in Equation (4) as an embodiment.

Here, d _j is a wireless terminal 100 and the second access is the distance between point 120, I _j is the coverage 320 of the wireless station 100 CS range 300 and the second access point 120 of the At the intersection of the first access point and the second access point.

d _j and I _j can be computed similar to d and I in equation (2). Instead, r _i is the RSSI value of the second access point 120 measured at the wireless terminal 100, and the minimum RSSI value for the wireless terminal 100 to transmit data to and receive data from the second access point 120 is applied .

)을 추정할 수 있다. Finally, the wireless terminal 100 uses the equation (5) to calculate the interference component (" 1 ") representing the channel usage of the second access point 120 in the interference region 321

) Can be estimated.

는 제2액세스 포인트(120)의 채널 사용량, 즉 제2액세스 포인트(120)에 접속한 무선 단말들의 채널 사용량을 나타낸다. 간섭 성분(

)은 제2액세스 포인트(120)의 간섭 영역(321) 및 채널 사용량(

)에 비례할 수 있다.here,

Represents a channel usage amount of the second access point 120, that is, a channel usage amount of wireless terminals connected to the second access point 120. [ Interference component (

Of the second access point < RTI ID = 0.0 > 120 < / RTI &

). ≪ / RTI >

If the number of hidden nodes and the interference component are estimated, the wireless terminal according to the present invention calculates the throughput for the first access point (S220) using the number of hidden nodes and the interference component estimated in step S210.

The throughput for the first access point 110 may be reduced in proportion to the number of hidden nodes and the interference component, and more specifically, the wireless terminal 100 may use the Equation (6) The throughput S for the point 110 can be calculated.

Each of P _success , P _idle and P _collision is a transmission success probability of a packet having an average packet size E [L] between the wireless terminal 100 and the first access point 110 in one time slot, (Idle) and packet collision probability that the packet is not transmitted or received, and can be calculated as shown in Equation (7). T _s and T _c represent average busy time due to packet transmission success and average busy time due to packet collision, and can be calculated as shown in Equation (8).

In Equation (7), p represents a probability that the wireless terminal 100 transmits a packet in a time slot, and P _L represents a packet error rate (PER) due to a packet collision between wireless terminals. n _c represents the average number of wireless terminals included in the CS area 300 of the wireless terminal 100 and can be calculated as shown in Equation (9).

는 제1액세스 포인트와 동일 채널을 이용하는 액세스 포인트의 집합을 나타내고, 도 3에서 제2액세스 포인트(120)가

집합에 포함된다.Here,? Is a constant,

Represents a set of access points using the same channel as the first access point, and in FIG. 3, the second access point 120

Are included in the set.

Meanwhile, the PER may increase with an increase in the number of hidden nodes that are not detected by the wireless terminal 100, and the wireless terminals included in the CS region 300 of the wireless terminal 100 may be increased by the wireless terminal 100 It can reduce the PER relative to the hidden node. Thus, this relationship can be defined as: " (10) "

), 그리고 [수학식 6] 내지 [수학식 10]을 이용하여 제1액세스 포인트(110)의 쓰루풋을 계산할 수 있다. As a result, in step S220, the wireless terminal calculates the number (n _h ) of estimated hidden nodes and the interference component

), And [Equation 6] to [Equation 10], the throughput of the first access point 110 can be calculated.

Then, the wireless terminal determines whether to connect to the first access point using the calculated throughput (S230). At this time, the wireless terminal determines a connection to the first access point when the throughput for the first access point is the maximum among the throughputs for the access point around the wireless terminal.

Then, the wireless terminal accesses the first access point using the CCAT value when the throughput is maximum.

As described above, the wireless terminal may also calculate throughput for the second access point, and may connect to the second access point if the throughput for the second access point is greater than the throughput of the first access point.

4 is a flowchart illustrating a method of access point connection of a wireless terminal in a wireless LAN network according to a specific embodiment of the present invention.

)으로 초기화하고, 최대 쓰루풋 값(

) 및 최대 쓰루풋 값에 대한 CCAT 값(

)을 0으로 초기화(S410)한다.The wireless terminal according to the present invention sets the initial CCAT value (P _C )

), And the maximum throughput value (

) And the CCAT value for the maximum throughput value (

Is initialized to 0 (S410).

Then, the wireless terminal estimates the number of hidden nodes and the interference components using the predetermined CCAT value, and calculates the throughput using a function S _i (P _C ) that returns the throughput according to the CCAT value (S420). As described above, the throughput can be calculated from [Equation 6] to [Equation 9] using the number of hidden nodes included in the hidden region and the interference component as parameters, (9) can constitute the throughput return function S _i (P _C ).

)을 비교(S430)하고, 계산된 쓰루풋 값이 최대 쓰루풋 값(

)보다 큰 경우, 최대 쓰루풋 값(

) 및 최대 쓰루풋 값에 대한 CCAT 값(

)을 단계 S420에서 이용된 CCAT 값(P_C)과 단계 S420에서 계산된 쓰루풋 값으로 갱신(S440)한다.The wireless terminal calculates the throughput value and the maximum throughput value (

(S430), and the calculated throughput value is compared with the maximum throughput value (

), The maximum throughput value (

) And the CCAT value for the maximum throughput value (

) To the CCAT value (P _C ) used in step S420 and the throughput value calculated in step S420 (S440).

)만큼 증가시켜, 기 설정된 CCAT 값의 범위 내에 CCAT 값이 존재하는지 판단(S450)한다.Thereafter, the wireless terminal sets the CCAT value (P _C ) used for throughput calculation to a predetermined value (

), And determines whether there is a CCAT value within the predetermined CCAT value range (S450).

) 및 최대 쓰루풋 값에 대한 CCAT 값(

)으로 출력한다. If the increased CCAT value satisfies the predetermined CCAT value range, the wireless terminal returns to step S420 and calculates the throughput value again for the updated CCAT value. On the other hand, if the increased CCAT value does not satisfy the predetermined CCAT value range, the CCAT value and the throughput value in step S420 before increasing the maximum throughput value (

) And the CCAT value for the maximum throughput value (

.

)을 결정하고, 무선 단말 주변의 액세스 포인트에 대한 쓰루풋 중, 최대 쓰루풋 값(

)을 나탸내는 액세스 포인트로 CCAT 값(

)을 이용하여 접속한다.That is, within the range of the predetermined CCAT value, the wireless terminal calculates the CCAT value (

And determines, among the throughputs for the access points around the wireless terminal, the maximum throughput value (

The CCAT value (

).

FIG. 5 shows a scenario for simulating an access point connection method according to the present invention, and FIGS. 6 to 9 are diagrams for explaining simulation results according to the scenario of FIG.

More specifically, FIG. 5A shows a scenario in which access points and wireless terminals are relatively evenly distributed, and FIG. 5B shows a scenario in which the density of wireless terminals is high in a specific area (hot spot) . FIG. 5 (c) shows a scenario in which a specific area is around the access point, compared with FIG. 5 (b).

6 to 8 show the average throughput and the Jain's Fairness Index (JFI) of wireless terminals connected according to the conventional access point connection method (single-dsc, random-dsc) and the present invention (single-proposed, random-proposed) . FIG. 9 shows the average throughput of the wireless terminal according to the present invention and the present invention when the access points are arranged in a non-fixed and random manner. Here, 'single' indicates a case where the access points use the same channel, and 'random' indicates a case where the access points randomly select a channel among non-overlapping channels.

FIG. 6 shows the simulation results under the scenario conditions shown in FIG. 5 (a), FIG. 7 shows the simulation results under the scenario conditions shown in FIG. 5 (b), FIGS. 8 and 9 show the scenario conditions shown in FIG. Fig.

Referring to Figures 6-9, it can be seen that in all cases the throughput of the wireless terminal connected to the access point is higher according to the present invention. Also, according to the present invention, fairness of a wireless LAN network is improved.

The above-described technical features may be implemented in the form of program instructions that can be executed through various computer means and recorded in a computer-readable medium. The computer-readable medium may include program instructions, data files, data structures, and the like, alone or in combination. The program instructions recorded on the medium may be those specially designed and constructed for the embodiments or may be available to those skilled in the art of computer software. Examples of computer-readable media include magnetic media such as hard disks, floppy disks and magnetic tape; optical media such as CD-ROMs and DVDs; magnetic media such as floppy disks; Magneto-optical media, and hardware devices specifically configured to store and execute program instructions such as ROM, RAM, flash memory, and the like. Examples of program instructions include machine language code such as those produced by a compiler, as well as high-level language code that can be executed by a computer using an interpreter or the like. The hardware device may be configured to operate as one or more software modules to perform the operations of the embodiments, and vice versa.

As described above, the present invention has been described with reference to particular embodiments, such as specific elements, and specific embodiments and drawings. However, it should be understood that the present invention is not limited to the above- And various modifications and changes may be made thereto by those skilled in the art to which the present invention pertains. Accordingly, the spirit of the present invention should not be construed as being limited to the embodiments described, and all of the equivalents or equivalents of the claims, as well as the following claims, belong to the scope of the present invention .

Claims (10)

Adjusting a CCAT value, estimating the number of hidden nodes for the first access point and the interference component for the second access point;
Calculating a throughput for the first access point using the number of hidden nodes and the interference component;
Using the throughput to determine whether to connect to the first access point
The method comprising the steps of:
The method according to claim 1,
The step of estimating the interference component
Calculating a hidden area of the first access point for the wireless terminal according to the CCAT value; And
Estimating the number of hidden nodes included in the hidden area using the hidden area and the number of nodes connected to the first access point
The method comprising the steps of:
The method according to claim 1,
The step of estimating the interference component
Calculating an interference region of the second access point for a wireless terminal according to the CCAT value; And
Estimating the interference component indicating the channel usage amount of the second access point in the interference region using the interference region and the channel usage amount of the second access point
The method comprising the steps of:
The method according to claim 1,
The step of estimating the interference component
Adjusting the CCAT value by a preset value within a predetermined range, estimating the number of hidden nodes and the interference component
A wireless terminal access point access method in a wireless LAN network.
The method according to claim 1,
Wherein determining whether to connect to the first access point comprises:
Determining a connection to the first access point if the throughput for the first access point is at a maximum during throughput for the access point around the wireless terminal
A wireless terminal access point access method in a wireless LAN network.
6. The method of claim 5,
Accessing the first access point using a CCAT value when the throughput is maximum;
Wherein the access point is a wireless LAN access point.
Estimating a number of hidden nodes for the first access point and an interference component for the second access point using the predetermined CCAT value;
Calculating a throughput for the first access point using the number of hidden nodes and the interference component;
Determining a CCAT value within which the throughput is maximized within a predetermined CCAT value; And
Accessing the first access point using a CCAT value with the maximum throughput when the throughput for the first access point is the maximum among throughputs for the access point around the wireless terminal
The method comprising the steps of:
An information receiver for receiving a beacon frame from the first and second access points;
An information estimator for adjusting the CCAT value and estimating the number of hidden nodes for the first access point and the interference component for the second access point;
A throughput calculation unit for calculating a throughput for the first access point using the number of hidden nodes and the interference component; And
A connection determination unit for determining whether to connect to the first access point using the throughput,
Gt;
9. The method of claim 8,
The information estimating unit
The hidden node of the first access point and the number of nodes connected to the first access point in accordance with the CCAT value to estimate the number of the hidden nodes included in the hidden area, government; And
Using the interference region of the second access point and the channel usage amount of the second access point for the wireless terminal according to the CCAT value to calculate the interference component indicating the channel usage amount of the second access point in the interference region The estimated interference component estimator
Gt;
9. The method of claim 8,
The first and second access points
An access point using the same channel
Wireless terminal.

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