KR101470872B1 - Method for allocating optimum channel of AP for Wi-Fi network - Google Patents

Abstract

The present invention relates to an AP optimal channel allocation method for Wi-Fi network design. More particularly, to an AP optimal channel allocation method for designing a Wi-Fi network capable of allocating an optimal frequency channel for minimizing mutual signal interference to each of a plurality of APs arranged for a Wi-Fi network implementation. (a) calculating a coverage overlay for each of a plurality of APs with each of the other APs; (b) allocating an outermost channel among the plurality of APs to an AP having a maximum sum of coverage overlaps with each of the other APs; (c) allocating, to the AP having the largest coverage overlap with each of the channel-assigned AP and the other APs in the step (b), to the outermost channel allocated in the step (b) Assigning a channel; (d) selecting an AP having a maximum sum of coverage overlaps with channel-unassigned APs as channel-unassigned APs; (e) a channel having a minimum sum of degree of signal interference between the AP selected in the step (d) and each of the APs allocated to the channel among the allotable channels is selected as a channel of the AP selected in the step (d) Assigning; And (f) repeating the steps (d) and (e) for the remaining channel unassigned APs until a channel is allocated to all of the channel unassigned APs other than the channel-allocated APs .

Description

The present invention relates to an AP optimal channel allocation method for a Wi-Fi network design,

The present invention relates to an AP optimal channel allocation method for Wi-Fi network design. More particularly, to an AP optimal channel allocation method for designing a Wi-Fi network capable of allocating an optimal frequency channel for minimizing mutual signal interference to each of a plurality of APs arranged for a Wi-Fi network implementation.

In the case of a frequency channel allocated to each of a plurality of APs arranged for the implementation of a Wi-Fi network, a superposed channel in which frequencies are overlapped and an independent channel in which frequencies do not overlap can be distinguished from each other due to the characteristics of a Wi-Fi network using a standardized channel bandwidth , It is generally recommended to use an independent channel in the case of AP channel allocation in a Wi-Fi network. However, in the case where a plurality of APs are densely arranged, redundant allocation of independent channels becomes inevitable in reality.

In the case of the redundant allocation of the independent channels, there is a possibility of generating a high mutual signal interference between a plurality of APs compared to the case of allocating the overlapping channels. Such a signal interference may cause a problem .

In addition, when an overlapping channel is allocated, a channel allocation is mainly performed according to the distance between APs. In this case, there is a problem in minimizing mutual signal interference between APs.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to overcome the above-mentioned problems by providing a method of overlaying coverage between a plurality of APs using RSSI (Received Signal Strength Indicator) predicted values at a plurality of observation points for each of a plurality of APs And an optimal AP allocation method for designing a Wi-Fi network capable of allocating an optimal frequency channel that can be minimized to each AP.

According to another aspect of the present invention, there is provided a method of optimizing an AP for a Wi-Fi network, the method comprising: (a) calculating a coverage overlay with each of a plurality of APs; (b) allocating an outermost channel among the plurality of APs to an AP having a maximum sum of coverage overlaps with each of the other APs; (c) allocating, to the AP having the largest coverage overlap with each of the channel-assigned AP and the other APs in the step (b), to the outermost channel allocated in the step (b) Assigning a channel; (d) selecting an AP having a maximum sum of coverage overlaps with channel-unassigned APs as channel-unassigned APs; (e) a channel having a minimum sum of degree of signal interference between the AP selected in the step (d) and each of the APs allocated to the channel among the allotable channels is selected as a channel of the AP selected in the step (d) Assigning; And (f) repeating the steps (d) and (e) for the remaining channel unassigned APs until a channel is allocated to all of the channel unassigned APs other than the channel-allocated APs .

The method may further include generating a RSSI (Received Signal Strength Indicator) predicted value at each of a plurality of observation points for each of a plurality of APs prior to the step (a) It is possible to calculate the overlap degree of coverage with each of the other APs.

In addition, in the step (a), the coverage overlap can be calculated by the following equation.

Here, G _ij is a coverage overlay of AP i and AP j, Y is the number of observation points, F _iy is a threshold value determination coefficient of the RSSI predicted value at the observation point y by AP i, and F _jy is AP j Means a coefficient for determining whether the RSSI predicted value at the observation point y exceeds the threshold value.

In the step (e), the degree of signal interference may be calculated by the following equation.

Here, H _{j (n)} is a signal interference with the channel group assigned to AP when assigning the channel n to the AP j, G _ij is the coverage overlap of the channel group assigned to AP i and the channel unassigned AP j FIG, n _i is The channel of the channel-based AP i, and X _C denote the number of channel-based APs.

According to the present invention, considering coverage overlap between a plurality of APs arranged to implement a Wi-Fi network, a frequency channel capable of minimizing mutual signal interference can be allocated to each AP, thereby providing a high-quality Wi-Fi service .

1 is a flowchart of an AP optimum channel allocation method for designing a Wi-Fi network according to a preferred embodiment of the present invention, and FIG.
FIGS. 2 to 8 are reference diagrams for a method of allocating an AP optimal channel for designing a Wi-Fi network according to a preferred embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. It should be noted that, in the case of adding the reference numerals to the respective constituent elements, the same constituent elements are denoted by the same reference numerals as much as possible even if they are shown in different drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. Further, the preferred embodiments of the present invention will be described below, but it is needless to say that the technical idea of the present invention is not limited thereto and can be practiced by those skilled in the art.

FIG. 1 is a flowchart illustrating an AP optimum channel allocation method for designing a Wi-Fi network according to a preferred embodiment of the present invention. FIGS. 2 to 8 are flowcharts illustrating AP optimum for a Wi-Fi network design according to a preferred embodiment of the present invention. A reference diagram for a channel allocation method.

The AP optimal channel allocation method for designing a Wi-Fi network according to a preferred embodiment of the present invention will be described with reference to FIGS. 1 to 8 as follows.

As shown in FIG. 1, a RSSI (Received Signal Strength Indicator) predicted value is generated for each of a plurality of APs arranged in an area where a Wi-Fi network is implemented in each of a plurality of observation points determined in advance in the area.

At this time, in step S10, the RSSI predicted value may be generated using a ray tracing model or the like, for example, in a predetermined propagation environment model.

In step S20, the coverage overlay with each of the other APs is calculated for each of the plurality of APs.

For example, when the AP # 1, the AP # 2, the AP # 3, and the AP # 4 are arranged in the area where the WiFi network is implemented and the frequency channels assignable to the AP # 1 to AP # 4 are CH1, CH2, CH3, , CH5, and CH6, it is possible to calculate the coverage overlap with each of the other APs by AP # 1 to AP # 4 as shown in FIG. 2. In other words, in the case of AP # 1, coverage and also G _12, the coverage overlap G between the AP # 3 _13, AP # coverage overlap of Figure 4 it is possible to calculate a G _14, AP # 2 to AP # s 4 to another AP in the same way in each case possible to calculate the overlap and coverage overlap G ₁₂ and G _21, G ₁₃ and G _31, G ₁₄ and G _41, G ₂₃ and G _32, G ₂₄ and G _42, and G ₃₄ and G ₄₃ have the same value, Lt; / RTI >

At this time, in S20, the coverage overlap can be calculated by the following equation (1).

Here, G _ij is a coverage overlay of AP i and AP j, Y is the number of viewpoints, F _iy is a threshold value exceeding threshold value determination _flag 1 of RSSI predicted value (R _iy ) at observation point y by AP i Or 0), and F _jy means a threshold value exceedance determination coefficient (1 or 0) of the RSSI predicted value (R _jy ) at the observation point y by AP j.

In this case, in the case of F _iy and F _jy , it may be 1 when the RSSI predicted value at the observation point y by AP i and AP j exceeds the RSSI threshold (R _T ) per predetermined Wi-Fi service, The RSSI threshold for each Wi-Fi service may be determined according to the main purpose of the Wi-Fi network to be implemented. In a case where web browsing is mainly performed in a Wi-Fi network implemented, the RSSI threshold per Wi-Fi service may be -75 dBm And the RSSI threshold for each Wi-Fi service may be -65 dBm when video streaming is mainly performed in a Wi-Fi network to be implemented.

In step S30, an AP having a maximum sum of coverage overlaps with each of the plurality of APs is determined. In step S40, an AP having a maximum sum of the coverage overlaps determined in step S30 is allocated to an AP .

At this time, as shown in FIG. 2, the AP # 1, the AP # 2, the AP # 3, and the AP # 4 allocated to the area where the Wi-Fi network is implemented It is possible to calculate the sum of the coverage overlaps with each of the APs, and as shown in FIG. 3, it is possible to allocate the APs # 1 to AP # The outermost channel CH1 among the channels can be allocated.

Here, the number of frequency channels that can be allocated to the plurality of APs is not limited to this, and it is also possible to allocate CH6, which is the other outermost channel for allocating CH1 to AP # 3.

In step S50, the outermost channel allocated to the outermost channel allocated in step S40 of the assignable channel is allocated to the AP having the maximum coverage overlap with the AP allocated to the outermost channel and the other APs, respectively.

At this time, as shown in FIG. 4, the value of G ₃₁ among the coverage overlaps G ₃₁ , G ₃₂ , and G ₃₄ is the maximum, and in case of AP # 3, CH 1, which is the outermost channel among the channels allocable to all APs, , It is possible to allocate CH # 6, which is the outermost channel to CH # 1, to AP # 1.

In step S60, the AP having the largest sum of coverage overlaps with each of the channel-allocated APs among the channel-unassigned APs is selected as the next channel allocation AP.

5, the sum of coverage overlaps of AP # 2 as a channel unassigned AP, AP # 1 and AP # 3 as channel-based APs, AP # 4 as a channel unassigned AP, AP # 1 and AP # 3, and then AP # 2 having the maximum sum of coverage overlaps according to the calculation result can be selected as the next channel allocation AP.

In step S70, a channel in which the sum of degree of signal interference between the AP selected as the next channel allocation AP and the channel allocated APs in S60 of the allotable channels becomes minimum is allocated to the AP selected in the next channel allocation AP in step S70 do.

At this time, the degree of signal interference can be calculated by the following equation (2).

Here, H _{j (n)} is a signal interference with the channel group assigned to AP when assigning the channel n to the AP j, G _ij is the coverage overlap of the channel group assigned to AP i and the channel unassigned AP j FIG, n _i is The channel of the channel-based AP i, and X _C denote the number of channel-based APs.

In addition, as shown in FIG. 6, in the coverage overlaps G ₁₂ and S 50 of the channel-assigned AP # 3 and the AP # 2 selected in the step S60, the coverage of the AP # 1 and the AP # 2 selected in the channel- The sum of the signal interference degrees of AP # 1 and AP # 2 and the signal interference degree of AP # 3 and AP # 2 can be obtained for each of CH1 to CH6 assignable to AP # 2 using superposition G ₂₃ , It is possible to assign CH4, which is the channel with the smallest sum of signal interference degrees, to AP # 2.

In step S90, it is checked whether or not all APs are allocated to the APs. If all the APs are assigned channels, the process ends. If all APs are not allocated with channels, the APs are removed from the APs in step S100. S60 to S90 are repeatedly performed until a channel is allocated to all unassigned APs, and when all the APs are allocated with a channel, termination is performed.

At this time, AP # 1 and AP # 4 are allocated to CH1 to CH6 that can be allocated to AP # 4 to which no channel is allocated among AP # 1, AP # 2, AP # 3 and AP # The sum of the degree of signal interference of AP # 2 and AP # 4, and the degree of signal interference of AP # 3 and AP # 4, 8, a CH 6 is assigned to AP # 1 according to an AP optimum channel allocation method for designing a Wi-Fi network according to a preferred embodiment of the present invention, CH 4 is assigned to AP # 2, CH 1 is assigned to AP # 3, and CH 6 is allocated to AP # 4. Thus, channel allocation for all APs that are currently deployed for Wi-Fi network implementation can be completed.

In the case of the AP optimum channel allocation method for Wi-Fi network design according to the present invention, for each of a plurality of APs arranged for a Wi-Fi network implementation, using the RSSI predicted values at each of a plurality of observation points, It is possible to allocate an optimal frequency channel to each AP so that mutual signal interference between a plurality of APs can be minimized by using the calculated coverage overlapping degree. As a result, It is possible to provide high-quality Wi-Fi services for a given area.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the invention as defined by the appended claims. It will be possible. Therefore, the embodiments disclosed in the present invention and the accompanying drawings are intended to illustrate and not to limit the technical spirit of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments and the accompanying drawings . It is intended that the present invention cover the modifications and variations of this invention provided they come within the scope of the appended claims and their equivalents.

Claims (4)

(a) calculating a coverage overlay for each of a plurality of APs with each of the other APs;
(b) allocating an outermost channel among the plurality of APs to an AP having a maximum sum of coverage overlaps with each of the other APs;
(c) allocating, to the AP having the largest coverage overlap with each of the channel-assigned AP and the other APs in the step (b), to the outermost channel allocated in the step (b) Assigning a channel;
(d) selecting an AP having a maximum sum of coverage overlaps with channel-unassigned APs as channel-unassigned APs;
(e) a channel having a minimum sum of degree of signal interference between the AP selected in the step (d) and each of the APs allocated to the channel among the allotable channels is selected as a channel of the AP selected in the step (d) Assigning; And
(f) repeating steps (d) and (e) for the remaining channel unassigned APs until a channel is allocated to all of the remaining channel unassigned APs except the channel-allocated APs AP optimal channel allocation method for Wi-Fi network design. The method according to claim 1,
Prior to the step (a)
Further comprising generating a RSSI (Received Signal Strength Indicator) predicted value at each of a plurality of observation points with respect to each of a plurality of APs, And calculating an overlapping degree of the Wi-Fi network. The method according to claim 1,
Wherein the coverage overlay in the step (a) is calculated by the following equation.

Here, G _ij is a coverage overlay of AP i and AP j, Y is the number of observation points, F _iy is a threshold value determination coefficient of the RSSI predicted value at the observation point y by AP i, and F _jy is AP j Means a coefficient for determining whether the RSSI predicted value at the observation point y exceeds the threshold value. The method according to claim 1,
Wherein the signal interference level in the step (e) is calculated by the following equation.

Here, H _{j (n)} is a signal interference with the channel group assigned to AP when assigning the channel n to the AP j, G _ij is the coverage overlap of the channel group assigned to AP i and the channel unassigned AP j FIG, n _i is The channel of the channel-based AP i, and X _C denote the number of channel-based APs.

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