KR101311228B1 - Device for assigning frequency automatically and method for assigning frequency automatically based on graph coloring - Google Patents

Abstract

PURPOSE: Frequency automatic designation apparatus and frequency automatic designation method thereof based on graph coloring are provided to improve the frequency interference calculation efficiency and frequency use efficiency when designating a frequency to a communication link. CONSTITUTION: For a plurality of communication links, frequency separation information is calculated to avoid frequency interference between the plurality of communication links (S110). A frequency designation order for each of the plurality of communication links based on each importance of the plurality of communication links, the number of frequency interference links for each of the plurality of communication links or the sum of estimated amount of frequency interference of the interference links is calculated (S120). Based on the frequency designation order and the frequency separation information, a frequency is designated to the each of the plurality of communication links (S130). [Reference numerals] (AA) Start; (BB) End; (S110) Calculate frequency separation information for a plurality of communication links to avoid frequency interference between the plurality of communication links; (S120) Determine frequency designation orders for each of the plurality of communication links; (S130) Designate frequencies to the each of the plurality of communication links based on the frequency designation order and the frequency separation information

Description

Automatic Frequency Assignment based on Graph Coloring and Automatic Frequency Assignment {DEVICE FOR ASSIGNING FREQUENCY AUTOMATICALLY AND METHOD FOR ASSIGNING FREQUENCY AUTOMATICALLY BASED ON GRAPH COLORING}

The present invention relates to a frequency automatic designation apparatus based on graph coloring and a frequency automatic designation method for a military wireless communication network design.

In general, in the private sector, the frequencies of additionally applied new stations are approved in the presence of licensed existing stations. If the frequency of the new radio station additionally applied is approved, it is determined whether the frequency of the new radio station uses a legally accepted frequency band, whether or not the new radio station interferes with the existing radio station, and the new radio station is It is determined whether or not it is interfered by the radio station. Through this determination process, the frequency of the new radio station can be approved. That is, in the private sector, in the process of approving a frequency to a new radio station, frequency interference between one new radio station and an existing radio station is analyzed, and a frequency may be designated in units of one new radio station.

In the case of the military, when designing a wireless communication network according to military operations, frequency is frequently assigned to a plurality of wireless devices. To this end, some military radio wave analysis tools overseas have a function of automatically assigning frequencies collectively, but specific algorithms of this function are not disclosed.

The ROK military uses the automatic frequency assignment of foreign radio wave analysis tools to designate frequencies for a number of wireless devices when designing a wireless network for military operations. Therefore, it is necessary to secure a technology for automatic domestic frequency designation.

Basically, in one new wireless device unit, it is determined whether or not to interfere with the existing wireless device and whether or not it is interfered by the existing wireless device, and accordingly, frequency batch automatic assignment is possible.

However, when frequency assignment is performed using L frequencies for N wireless devices, interference determination of N (N-1) for L frequencies according to the frequency assignment order of N! (Factorial) should be performed. In the worst case, the frequency interference of N! × N (N−1) × L should be calculated. To this end, an enormous time is required, and there is a problem that the use efficiency of the frequency is not guaranteed.

It is an object of the present invention to provide a graph coloring based frequency automatic designation apparatus and a frequency automatic designation method that can improve frequency interference calculation efficiency and frequency use efficiency when designating a frequency in a communication link.

According to an embodiment of the present invention, a method for automatically assigning a frequency based on graph coloring includes: calculating frequency separation information for each of a plurality of communication links to avoid frequency interference between the plurality of communication links; A frequency designation of each of the plurality of communication links based on the importance of each of the plurality of communication links, the number of frequency interference links for each of the plurality of communication links, or the sum of the frequency interference prediction amount of each of the interference links Determining an order; And assigning a frequency to each of the plurality of communication links based on the frequency specification order and the frequency separation information.

The calculating of the frequency separation information may include: calculating a frequency interference prediction amount of each of the interference links; And calculating the frequency separation information by using the frequency interference prediction amount and a net filter discrimination (NFD) graph.

The calculating of the frequency interference prediction amount of each of the interference links may be performed by calculating the frequency interference prediction amount of each of the plurality of communication links based on Equation 1 below.

[Equation 1]

(EIL (x): Frequency Interference Prediction, x: Interference Link, f: Frequency of Interference Radio Equipment, P _tx : Output of Interference Radio Equipment, G _tx : Antenna Gain of Interference Radio Equipment, PL _{tx → rx} : Interference Radio Equipment Propagation loss, G _rx : antenna gain of interference radio equipment, T _rx : reception limit level of interference radio equipment)

In an embodiment, the calculating of the frequency separation information using the frequency interference prediction amount and the integrated filter discrimination graph may include calculating the frequency separation information based on Equation 2 below.

&Quot; (2) "

(g (x): frequency separation required to attenuate the interference interference amount of the interference link, EIL (x): frequency interference prediction amount, x: interference link, A: set of interference links, F _nfd (x): integrated filter differential graph Function)

The determining of the frequency assignment order of each of the plurality of communication links may include determining the frequency assignment order of each of the plurality of communication links based on the importance of each of the plurality of communication links. step; Determining frequency order of each of the plurality of communication links based on the number of frequency interference links for each of the plurality of communication links if the importance is the same; And if the number of frequency interference links is the same, determining a frequency designation order of each of the plurality of communication links based on the sum of the frequency interference prediction amounts of each of the interference links.

The determining of the frequency designation order of each of the plurality of communication links may include: grouping communication links having the same importance and the same number of frequency interference links among the plurality of communication links; By constructing an ordering tree using groups, determining a frequency designation order of each of the plurality of communication links.

The assigning a frequency to each of the plurality of communication links may include selecting a communication link to designate a frequency among the plurality of communication links based on the frequency designation order; Extracting some of the plurality of frequencies using the frequency spacing information for the selected communication link; And assigning a frequency to the selected communication link based on a predetermined number or frequency values of the extracted frequencies.

The extracting of some of the plurality of frequencies may include extracting some of the plurality of frequencies based on Equation 3 below.

&Quot; (3) "

(v: communication link to specify frequency, u: communication link specified and adjacent to v, C (u): frequency value of the frequency specified communication link, w _e (e _vu ): the interference link from v to u The greater of the frequency spacing needed to attenuate the frequency interference predictive value and the frequency spacing required to attenuate the interference interference from u to v, f: the frequency within the frequency spacing centered on C (u), F _C : radio equipment Set of frequency candidates to be assigned to)

According to the present invention, the frequency interference calculation efficiency can be improved by using simple arithmetic calculations instead of complex calculations when determining the frequency interference.

In addition, according to the present invention, by determining the importance of the communication link when determining the frequency designation order, the frequency can be assigned to the communication link of higher importance.

In addition, according to the present invention, the frequency designated at the time of frequency designation is designated as a priority, the reuse rate of the frequency can be improved. Accordingly, frequency resources can be used more efficiently.

1 is a flowchart illustrating a method for automatically assigning frequencies based on graph coloring according to an embodiment of the present invention.
2 and 3 are conceptual views illustrating a plurality of communication links and interference links in the graph coloring based frequency automatic designation method according to FIG. 1.
4 is a conceptual diagram illustrating a method of calculating frequency separation information in the method for automatically assigning frequencies based on graph coloring according to FIG. 1.
FIG. 5 is a conceptual diagram illustrating a method of selecting one of first and second directional links in the method for automatically assigning frequencies based on graph coloring according to FIG. 1.
6 and 7 are conceptual views illustrating a method of determining a new frequency designation order in the graph coloring based frequency automatic designation method according to FIG. 1.
FIG. 8 is a conceptual diagram illustrating a method of designating a frequency in the method for automatically designating a frequency based on graph coloring according to FIG. 1.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings so that those skilled in the art may easily implement the technical idea of the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

1 is a flowchart illustrating a method for automatically assigning frequencies based on graph coloring according to an embodiment of the present invention.

Referring to FIG. 1, first, a step S110 of calculating frequency separation information for avoiding frequency interference between a plurality of communication links for each of a plurality of communication links is performed.

In one embodiment of the present invention, a communication link of a wireless device that requires frequency designation may include a set of taps V = {v ₁ , v ₂ ,... , v _n }, and the interference link to the communication link of the wireless device is defined as the corner set A = {a ₁ , a ₂ ,. , a _n }.

The calculator may calculate the frequency interference prediction amount of each of the interference links. Here, the estimated interference level (EIL) refers to the estimated amount of frequency interference that the interference link gives to the interfered link. The calculator may calculate the frequency interference prediction amount of each of the interference links based on Equation 1 below.

Here, EIL (x) means the frequency interference prediction amount, x means the interference link, f means the frequency of the interference radio equipment. In addition, P _tx is the output of the interference radio equipment, G _tx is the antenna gain of the interference radio equipment, PL _{tx → rx} is the radio wave loss of the interference radio equipment, G _rx is the antenna gain of the interference radio equipment, T _rx is the interference radio Receive limit level of the equipment.

When calculating the interference interference amount, when the transmitting and receiving radio equipment of the interference link is the same type, the calculator may use the minimum frequency and the maximum frequency of the frequency band allocated to the transmitting and receiving radio equipment for f. On the other hand, when the transmitting and receiving radio equipment of the interference link is heterogeneous, the calculation unit calculates the frequency interference prediction amount of the interference link using the minimum and maximum frequencies of the overlapping or adjacent portions of the frequency bands allocated to the transmitting and receiving radio equipment to f, The maximum of the results can be used.

Subsequently, the calculation unit may calculate frequency separation information using a frequency interference prediction amount and an integrated filter discrimination (NFD) graph. The calculator may calculate frequency separation information of each of the interference links based on Equation 2 below.

Where g (x) is the frequency spacing required to attenuate the interference interference amount of the interference link, EIL (x) is the frequency interference prediction amount, x is the interference link, A is the set of interference links, and F _nfd (x) Is a function of the NFD graph.

The NFD graph is generally used to calculate the attenuation of the transmit power over the separation of the center frequency. However, in one embodiment of the present invention, the NFD graph may be used to calculate frequency separation information required to attenuate the amount of frequency interference prediction of the interference link.

That is, since the function y = F _nfd (x) of the NFD graph is symmetric about the y-axis, the calculation unit uses the inverse function y = F _nfd ^{- 1} (x) in the range of x≥0 to _reduce the transmission power of the interfering wireless device. The frequency separation information required to decrease by EIL (x) can be calculated. On the other hand, when EIL (x) ≤ 0, since there is no frequency interference, g (x) = 0.

Meanwhile, the calculator may extract the first directional link and the second directional link in the reverse direction of the first direction among the interference links. The calculator may select one of the first and second directional links using the frequency separation information for each of the first and second directional links. In detail, the calculator may select one of the first and second directional links based on Equation 3 below.

Here, w _e (x) means a larger value between the frequency spacing required for attenuating the frequency interference predictive quantity of the interference link from v to u and the frequency spacing required for attenuating the frequency interference predictive quantity of the interference link from u to v. . g (x) means the frequency spacing required to attenuate the frequency interference prediction amount of the interference link, a _vu means the interference link from v to u, a _uv means the interference link from u to v.

That is, the calculation unit may direct the directed graph G = (V, A; g) (where V is a set of communication links, A is a set of interference links, and g is a frequency of an interference link to reduce the complexity of graph coloring). Can be converted into an undirected graph. That is, the calculator may select only one of the interference link from v to u and the interference link from u to v, and delete the other. In this case, the calculation unit selects an interference link having a larger frequency separation required to attenuate the frequency interference prediction amount, and selects a set of selected interference links E = {e ₁ , e ₂ ,. , e _m } can be generated.

On the other hand, the calculation unit may define the weight of the top of the graph, that is, the importance of the communication link (w _v ) in order to give priority to the important communication link according to the battlefield situation or the operation plan.

As described above, the problem of frequency designation of the tactical network can be finally expressed as a problem related to the color of the tap of the graph G = (V; w _v , E, w _e ).

Next, step S120 is performed in which a frequency designation order of each of the plurality of communication links is determined.

The ordering unit may determine the importance w _v (v) of each of the plurality of communication links, the number of frequency interference links dG (v) for each of the plurality of communication links, or the sum of the frequency interference prediction amounts of each of the interference links ( Based on Σw _e (e)), the frequency assignment order of each of the plurality of communication links can be determined.

Specifically, the order determiner may determine the frequency designation order of each of the plurality of communication links based on the importance of each of the plurality of communication links. In this case, when the importance level is the same, the order determiner may determine a frequency designation order of each of the plurality of communication links based on the number of frequency interference links for each of the plurality of communication links. In this case, when the number of frequency interference links is the same, the order determiner may determine the frequency designation order of each of the plurality of communication links based on the sum of the frequency interference prediction amounts of each of the interference links.

On the other hand, when the above-mentioned frequency designation order determination fails, the order determiner may determine a new frequency designation order. In this case, the order determiner divides the taps having the importance w _v (v) of each of the same plurality of communication links and the number of frequency interference links dG (v) for each of the plurality of communication links into groups. You can also construct a decision tree.

Thereafter, in step S130, a frequency is assigned to each of the plurality of communication links based on the frequency designation order and the frequency separation information.

The frequency designation unit selects a communication link to designate a frequency among the plurality of communication links based on the frequency designation order, and extracts some of the plurality of frequencies by using frequency separation information on the selected communication link. In detail, the frequency designation unit may extract some of the plurality of frequencies based on Equation 4 below.

Here, v denotes a communication link to designate a frequency, u denotes a communication link adjacent to v and a frequency specified, and C (u): a frequency value of a frequency-linked communication link. w _e (e _vu ) means the greater of the frequency spacing required to attenuate the frequency interference prediction amount of the interference link from v to u and the frequency spacing required to attenuate the frequency interference prediction amount of the interference link from u to v, f Denotes a frequency within the frequency separation around C (u), and F _C denotes a set of frequency candidates to be assigned to the wireless equipment.

The frequency designator may determine a frequency to be assigned to the selected communication link based on a predetermined number of extracted frequencies. In detail, the frequency designation unit may assign, to the selected communication link, a frequency having a predetermined number of times as a priority. If the frequency is designated, the frequency designation unit may increase the value of the function p (x) indicating the frequency designation frequency.

If the predetermined number of times is the same, the frequency designation unit may determine a frequency to be assigned to the selected communication link based on the frequency value. In detail, the frequency designation unit may designate a minimum frequency among the extracted frequencies to the selected communication link.

2 and 3 are conceptual views illustrating a plurality of communication links and interference links in the graph coloring based frequency automatic designation method according to FIG. 1.

Referring to FIG. 2, a communication link between a plurality of wireless devices H1, H2, H3, H4, H5, and H6 and an interference link for a communication link may be known. Here, the communication link is shown by the solid line and the interference link is shown by the dotted line. At this time, the communication link between the plurality of wireless devices is set in the graph set V = {v ₁ , v ₂ ,... , v _n }. In addition, the interference link for the plurality of communication links is set to the edge set A = {a ₁ , a ₂ ,... , a _n }.

Referring to FIG. 3, an interference link for the communication links H12, H21, H34, H43, H56, and H65 can be seen.

4 is a conceptual diagram illustrating a method of calculating frequency separation information in the method for automatically assigning frequencies based on graph coloring according to FIG. 1.

Referring to FIG. 4, a method of calculating frequency separation information using a Net Filter Discrimination (NFD) graph may be known.

The NFD graph is generally used to calculate the attenuation of the transmit power over the separation of the center frequency. However, in one embodiment of the present invention, y = _nfd F (x) inverse function of y = F _nfd ^-1 (x) by using the transmission power of the interfering radio equipment is to calculate the frequency separation information needed to decrease by a certain value of Can be.

FIG. 5 is a conceptual diagram illustrating a method of selecting one of first and second directional links in the method for automatically assigning frequencies based on graph coloring according to FIG. 1.

To reduce the complexity of graph coloring, the directed graph G = (V, A; g), where V is the set of communication links, A is the set of interference links, and g is the attenuation of the frequency interference estimate of the interfering links. Frequency spacing required to be converted into an undirected graph. That is, the calculator may select only one of the interference link from v to u and the interference link from u to v, and delete the other. In this case, the calculation unit selects an interference link having a larger amount of predicted frequency interference, and the set of selected interference links E = {e ₁ , e ₂ ,... , e _m } can be generated.

6 and 7 are conceptual views illustrating a method of determining a new frequency designation order in the graph coloring based frequency automatic designation method according to FIG. 1.

6 and 7, when the above-described frequency designation order determination fails, the order determination unit may determine a new frequency designation order. In this case, the order determiner divides the taps having the importance w _v (v) of each of the same plurality of communication links and the number of frequency interference links dG (v) for each of the plurality of communication links into groups. You can also construct a decision tree.

For example, if each group is referred to as L, M, N in the order of sorting, the order determining unit may construct a tree in reverse order from Root. Root is N [0], N [1],... Which are permutations from group N. , N [x] as child nodes, each N [0], N [1],... , N [x] are the permutations M [0], M [1],... Has M [y] as its child node. Finally, M [0], M [1],... , M [y] is a permutation of L [0], L [1],... Has L [z] as its child node. The new frequency-specified order uses the (Leaf, Root) -path from the second left to the path from each Leaf node in the ordering tree to Root.

The ordering tree holds only the index values for generating the permutation of the vertices of each group on the (Leaf, Root) -path. L [0] in the L group with z taps is the first sorted tap permutation. In the case of L [k], the order determining unit selects k / (zi)! Th tap v∈L [0] from L = 1 to L [0] as the first tap, and L [k as the i + 1th tap. Calculate 0] = L [0]-{v}, k = k% (zi) !, i = i + 1, and then change the k / (zi)! Th tap u∈L [0] of L [0]. Select, and finally generate L [k] by selecting the last tap remaining in L [0] when i = z.

FIG. 8 is a conceptual diagram illustrating a method of designating a frequency in the method for automatically designating a frequency based on graph coloring according to FIG. 1.

Referring to FIG. 8, f ₂ is assigned to H34, and frequencies f ₁ , f ₂ , and f ₃ can interfere with H56 within the frequency separation, and f ₆ is assigned to H21, so that the frequency that can interfere with H56 within the frequency separation is f _5. , f ₆ , f ₇ , the frequency candidate set to be specified in H56 may be F _c = {f ₄ , f ₈ , f ₉ }.

The apparatus for automatically specifying a frequency and the frequency automatic designation based on the graph coloring described above are not limited to the configuration and method of the above-described embodiments, but the embodiments may be modified in various ways. All or some of these may optionally be combined.

Claims (8)

For each of the plurality of communication links, calculating frequency separation information to avoid frequency interference between the plurality of communication links;
A frequency designation of each of the plurality of communication links based on the importance of each of the plurality of communication links, the number of frequency interference links for each of the plurality of communication links, or the sum of the frequency interference prediction amount of each of the interference links Determining an order; And
And assigning a frequency to each of the plurality of communication links based on the frequency specification order and the frequency separation information. The method of claim 1,
The step of calculating the frequency separation information,
Calculating a frequency interference estimate of each of the interference links; And
And calculating the frequency separation information by using the frequency interference prediction amount and a net filter discrimination (NFD) graph. 3. The method of claim 2,
Computing the frequency interference prediction amount of each of the interference links,
A method for automatically assigning frequency based on graph coloring, characterized in that for calculating the frequency interference prediction amount of each of the plurality of communication links based on Equation 1 below.
[Equation 1]

(EIL (x): Frequency Interference Prediction, x: Interference Link, f: Frequency of Interference Radio Equipment, P _tx : Output of Interference Radio Equipment, G _tx : Antenna Gain of Interference Radio Equipment, PL _{tx → rx} : Interference Radio Equipment Propagation loss, G _rx : antenna gain of interference radio equipment, T _rx : reception limit level of interference radio equipment) 3. The method of claim 2,
Computing the frequency separation information using the frequency interference prediction amount and the integrated filter discrimination graph,
A method for automatically assigning frequency based on graph coloring, characterized in that for calculating the frequency separation information based on Equation 2 below.
&Quot; (2) "

(g (x): frequency separation required to attenuate the interference interference amount of the interference link, EIL (x): frequency interference prediction amount, x: interference link, A: set of interference links, F _nfd (x): integrated filter differential graph Function) The method of claim 1,
Determining the frequency assignment order of each of the plurality of communication links,
Determining a frequency assignment order of each of the plurality of communication links based on the importance of each of the plurality of communication links;
Determining frequency order of each of the plurality of communication links based on the number of frequency interference links for each of the plurality of communication links if the importance is the same; And
And if the number of frequency interference links is the same, determining a frequency designation order of each of the plurality of communication links based on the sum of the frequency interference prediction amounts of each of the interference links. Automatic frequency assignment method. The method of claim 5, wherein
Determining the frequency assignment order of each of the plurality of communication links,
Grouping communication links having the same importance and having the same number of frequency interference links among the plurality of communication links, and constructing an ordering tree using a plurality of groups, thereby assigning a frequency assignment order to each of the plurality of communication links. And automatically determining the frequency based on the graph coloring. The method of claim 1,
Assigning a frequency to each of the plurality of communication links includes:
Selecting a communication link to designate a frequency among the plurality of communication links based on the frequency designation order;
Extracting some of the plurality of frequencies using the frequency spacing information for the selected communication link; And
And assigning a frequency to the selected communication link based on a predetermined number or frequency values of the extracted frequencies. The method of claim 7, wherein
Extracting some of the plurality of frequencies,
A method for automatically assigning frequencies based on graph coloring, wherein a part of the plurality of frequencies is extracted based on Equation 3 below.
&Quot; (3) "

(v: communication link to specify frequency, u: communication link specified and adjacent to v, C (u): frequency value of the frequency specified communication link, w _e (e _vu ): the interference link from v to u The greater of the frequency spacing needed to attenuate the frequency interference predictive value and the frequency spacing required to attenuate the interference interference from u to v, f: the frequency within the frequency spacing centered on C (u), F _C : radio equipment Set of frequency candidates to be assigned to)

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