KR20140104602A - Dipole antenna - Google Patents

Abstract

The present invention relates to a dipole antenna. The dipole antenna according to the present invention includes an insulation sheet; at least two pairs of radiation patterns arranged on a first surface of the insulation sheet; two or more feeding patterns which are arranged on a second surface of the insulation sheet to be electrically connected to the pairs of radiation patterns by penetrating the insulation sheet; and a secondary circuit which ensures distance from the feeding patterns to each of the radiation patterns to be equivalent.

Description

Dipole antenna "

The present invention relates to a dipole antenna, and more particularly, to a dipole antenna having at least two pairs of radiation pattern pairs on an insulating sheet, To a dipole antenna.

A dipole antenna is one of the most common types of antennas and generates horizontal or vertical polarized waves to transmit or receive electromagnetic waves. On the other hand, the dual polarized antenna is an antenna capable of simultaneously generating two polarized waves at a predetermined angle (+/- 45 degrees), unlike a general single polarized antenna having only vertical or horizontal polarized waves. The dual polarized antenna is widely used as a structure for reducing communication deterioration due to fading of a base station because it secures a channel through a polarization diversity of a mobile communication system. Therefore, broadband dual polarized dipole antenna technology is being developed in accordance with the data capacity of mobile communication system.

Generally, in order to realize dual polarization in a dipole antenna, at least two pairs of radiation patterns are provided, and each of the pairs of radiation patterns are aligned at right angles to each other to transmit two linearly polarized signals that can be aligned vertically and horizontally (Or received). Therefore, dual polarized dipole antennas can operate horizontally / vertically with a polarization direction of ± 45 degrees. Each radiation pattern pair of the dipole antenna transmits or receives a pair of vertical and horizontal polarized waves. In this case, complexity increases in constructing the power supply structure connected to each radiation pattern pair, which leads to an increase in the number of processes. Particularly, when the radiation pattern and the power supply structure are both provided on one insulating sheet, a phase difference due to the power feeding structure is generated, and the pattern of the emitted beam is not uniformly formed.

SUMMARY OF THE INVENTION In order to solve the above-mentioned problems, the present invention has a pair of radiation patterns and a feed pattern on one insulating sheet, and maintains the same distance between each radiation pattern constituting a pair of radiation patterns and the feed pattern, It is an object of the present invention to provide a dipole antenna that prevents a phase difference from occurring in a pattern of each beam of a pair.

The above object of the present invention can be achieved by providing an insulating sheet, at least two pairs of radiation patterns provided on a first surface of the insulating sheet, and a plurality of radiation patterns provided on a second surface of the insulating sheet, And at least two feed patterns electrically connected to each other and an auxiliary circuit for realizing distances between the feed pattern and individual radiation patterns forming each pair of the radiation patterns.

At least one of the two or more feeding patterns connected to the radiation pattern pair is connected through a pair of connection holes passing through the insulation sheet to avoid interference with the other. In this case, the power supply pattern provided with the connection hole is connected to each of the radiation pattern pairs through the through holes of the insulation sheet, and the auxiliary circuit is formed by a pair May be provided. Here, the auxiliary hole may be symmetrically provided in the connection hole around the through hole.

The power supply pattern provided with the connection hole is connected to each of the radiation pattern pairs through a through hole of the insulating sheet. The auxiliary circuit includes a bypass circuit provided on the opposite side of the connection hole with respect to the through hole . Here, the bypass circuit may be provided on the first surface on which the radiation pattern is formed. In this case, the total length of the bypass circuit is determined to be equal to the sum of the distance twice the thickness of the insulating sheet and the distance between the pair of connection holes.

The above object of the present invention can be also achieved by an insulating sheet, a pair of first radiation patterns and a pair of second radiation patterns vertically arranged on the first surface of the insulating sheet, A first feeding pattern and a second feeding pattern which are electrically connected to the first and second radiation pattern pairs through the through hole, and the distance between the respective feeding patterns and the respective radiation patterns forming the pair of radiation patterns are made equal And an auxiliary circuit which is connected to the antenna.

Here, the second feed pattern may be connected through a pair of connection holes passing through the insulation sheet to avoid interference with the first feed pattern. In this case, the second feeding pattern passes through the through-holes of the insulating sheet and is connected to each of the second radiation pattern pairs, and the auxiliary circuit is connected to the second feeding pattern on the opposite side A pair of auxiliary holes may be provided in the main body. The auxiliary hole may be symmetrically provided in the connection hole around the through hole.

The second feeding pattern passes through the through holes of the insulating sheet and is connected to each of the second radiation pattern pairs. The auxiliary circuit is arranged on the opposite side of the connecting hole along the second feeding pattern, A bypass circuit may be provided. Here, the bypass circuit may be provided on the first surface, and the total length of the bypass circuit may be determined to be equal to the sum of the distance of two times the thickness of the insulating sheet and the distance between the connection holes.

According to the dipole antenna having the above-described structure, it is possible to provide a simple and simple antenna having both a pair of radiation patterns and a feeding pattern in one insulating sheet.

Furthermore, the dipole antenna of the present invention can prevent the phase difference between the patterns of the emitted beams by keeping the connection distances between the radiation patterns and the power supply pattern, which form one pair of radiation patterns, the same, So that the beam pattern can be uniformly formed.

1 is a plan view of a dipole antenna according to an embodiment,
2 is a partially enlarged view of the 'A' region of FIG. 1,
3 is a sectional view taken along the line III-III in Fig. 2,
4 is a plan view of a dipole antenna according to another embodiment,
FIG. 5 is a partially enlarged view of the 'B' region of FIG. 4,
6 is a cross-sectional view taken along the line VI-VI in Fig. 5,
7 is a plan view of a dipole antenna according to still another embodiment,
8 is a partially enlarged view of the area 'C' in FIG.

Hereinafter, a dipole antenna according to various embodiments of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a plan view of a dipole antenna 100 according to one embodiment, and FIG. 2 is a partially enlarged view of an area 'A' of FIG.

1 and 2, the dipole antenna 100 includes an insulation sheet 10, at least two radiation patterns 102 and 104 provided on the first surface 12 of the insulation sheet 10, At least two feed patterns (152, 162) provided on the second surface (14) of the insulating sheet (10) and electrically connected to the radiation pattern pairs (102, 104) through the insulating sheet Respectively.

The pair of radiation patterns 102 and 104 is a basic element of wireless communication and radiates an electric signal transmitted through the power feeding patterns 152 and 162 in the form of an electron beam or receives electromagnetic waves by air conditioning, Power to the power feeding patterns 152 and 162, respectively.

The dipole antenna 10 has at least two pairs of radiation patterns 102 and 104 for realizing horizontal and vertical polarizations, i.e., dual polarization, and each radiation pattern pair 102 and 104 is perpendicular As shown in FIG. Thus, it becomes possible to transmit or receive two linearly polarized signals vertically and horizontally aligned. As a result, the dual polarized dipole antenna is configured such that the polarization direction is horizontally / vertically operable at an angle of 45 degrees. The radiation pattern pairs 102 and 104 of the dipole antenna transmit or receive a pair of vertical and horizontal polarized waves, respectively.

First, the dipole antenna 100 is formed by forming a predetermined pattern on the insulating sheet 10. The insulating sheet 10 provides a space for mounting the dipole antenna 100 and is generally manufactured by a printed circuit board (PCB) or a flexible printed circuit board (FPCB).

At least two pairs of radiation patterns 102 and 104 for radiating an electron beam may be provided on the first side 12 of the insulating sheet 10, 14, for example, at least two power supply patterns 152, 162 electrically connected to the radiation pattern pairs 102, 104, respectively. That is, the dipole antenna can be constituted by a simple and simple constitution including both the radiation pattern and the power supply pattern on the upper surface and the lower surface of the insulating sheet 10.

Specifically, the radiation patterns 110, 120, 130, and 140 may be extended from the central portion of the insulation sheet 10 toward the outside. In the figure, a first radiation pattern pair 102 and a second radiation pattern pair 104 are provided perpendicularly to a first surface 12 of an insulation sheet 10, A first feeding pattern 152 and a second feeding pattern 152 which are provided on the insulating sheet 14 and are electrically connected to the first radiation pattern pair 102 and the second radiation pattern pair 104 through the insulating sheet 10, 162 may be provided.

 The first radiation pattern 110 and the third radiation pattern 130 form a first radiation pattern pair 102. The second radiation pattern 120 and the fourth radiation pattern 140 form a pair 2 radiation pattern pair (104). The individual radiation patterns 110, 120, 130, 140 forming each pair are arranged perpendicular to each other, and the radiation pattern pairs are arranged so as to be perpendicular to each other.

On the other hand, the central portion of the insulating sheet 10 may be provided with a power feeding part A to which power feeding patterns 152 and 162 for supplying electric power in respective radiation patterns are connected. Specifically, the feed patterns 152 and 162 are formed on the second surface 14, that is, the lower surface of the insulating sheet 10, and the feed patterns 152 and 162 are formed in the through holes 150 and 160, respectively, 120, 130, and 140 of the first surface 12, respectively. That is, the power feeding pattern includes a first feeding pattern 152 electrically connected to the first radiation pattern pair 102 through the first through hole 150, and a second radiation pattern 152 through the second through hole 160. [ And a second feed pattern 162 electrically connected to the second feed pattern 104. The first feeding pattern 152 supplies power to the first radiation pattern 110 and the third radiation pattern 130 constituting the first radiation pattern pair 102. Further, The second radiation pattern 120 and the fourth radiation pattern 140 constituting the second radiation pattern pair 104 are supplied with electric power.

The first feeding pattern 152 and the second feeding pattern 162 are disposed in a direction perpendicular to the first radiation pattern pair 102 and the second feeding pattern 162. The first feeding pattern 152 and the second feeding pattern 162 are disposed at a central portion of the insulating sheet 10, Second radiation pattern pair 104, respectively. In this case, both the first feeding pattern 152 and the second feeding pattern 162 are connected to the radiation pattern pairs 102 and 104 on the first surface 12 of the insulating sheet 10, The second feed pattern 152 and the second feed pattern 162 need a structure that can avoid interference with each other. At least one of the two or more feeding patterns 152 and 162 connected to the pair of radiation patterns 102 and 104 may include a pair of first connections (not shown) penetrating the insulation sheet 10 to avoid interference with the other, Holes 20 and 22, respectively. Hereinafter, a more detailed description will be given with reference to the drawings.

3 is a sectional view taken along the line III-III in Fig.

3, the second feed pattern 162 includes a pair of connection holes 20 and 22 penetrating the insulating sheet 10 to avoid interference with the first feed patterns 152. In this embodiment, Lt; / RTI > Of course, unlike the drawing, the first feeding pattern 152 may be connected through the connection hole, and the feeding pattern provided with the connection hole may be appropriately determined.

3, a first feeding pattern 152 is formed along the first surface 12 of the insulating sheet 10 and a second feeding pattern 162 is formed between the first feeding pattern 152 and the first feeding pattern 152. [ Is formed on the second surface 14 through the insulating sheet 10 through the first connection hole 20 and is connected to the first surface 12 again through the second connection hole 22 in order to avoid interference. Therefore, the first feeding pattern 152 and the second feeding pattern 162 can be connected to the first radiation pattern pair 102 and the second radiation pattern pair 104 without interference with each other.

When power is supplied to all of the pair of radiation patterns by one power supply pattern as described above, it is necessary to supply power of the same phase in each radiation pattern. If a phase difference occurs in power supplied in a pair of radiation patterns, the radiation pattern of the electron beam emitted from the radiation pattern pair does not have desired directivity and / or range. Here, in order to supply the power of the same phase in each radiation pattern, the distance between the power supply pattern and each radiation pattern must be kept the same. However, if a connection hole for supplying power to each pair of radiation patterns by a pair of feeding patterns and for avoiding interference with one of the pair of feeding patterns is provided as described above, The power supplied through the pattern is phase-shifted. This is because the path connecting the feed pattern and the radiation pattern by the connection hole becomes longer.

1 and 2, a first through hole 150 to which a first feeding pattern 152 is connected when power is supplied to the first radiation pattern pair 102 by a first feeding pattern 152, The distances to the radiation patterns 110 and 130 constituting the first radiation pattern pair 102 are all equal to 'L ₁ + L ₂ '. Therefore, when power is supplied to the first radiation pattern pair 102 by the first feeding pattern 152, there is no phase difference between the radiation patterns 110 and 130.

When power is supplied to the second radiation pattern pair 104 by the second feeding pattern 162, the second radiation pattern pair (the first radiation pattern 162) is connected to the second radiation pattern pair 104 are different from each other.

That is, the distance from the second through hole 160 through which the second feeding pattern 162 is connected to the second radiation pattern 120 is' L ₃ + L ₁ ', but the distance to the fourth radiation pattern 140 is' L ₃ + L ₁ + 2T '. Here, 'T' corresponds to the thickness of the insulating sheet 10. When the second feeding pattern 162 is connected to the radiation patterns 120 and 140 constituting the second radiation pattern pair 104, the path including the connection holes 20 and 22 The first connection hole 20 is formed in the second surface 14 through the insulating sheet 10 and the second connection hole 22 is formed in the insulating sheet 10 by the second connection hole 22, (10) and connected to the first side (12). Therefore, as compared with the path in which the second feeding pattern 162 and the second radiation pattern 120 are connected (that is, the path not including the connection hole), the length of the insulating sheet 10 is longer . As a result, when power is supplied to the second radiation pattern pair 104 by the second feeding pattern 162, the length of the path connected to each radiation pattern 120, 140 constituting the second radiation pattern pair 104 So that a phase difference occurs in the power supplied to each of the radiation patterns 120 and 140. This makes it impossible to uniformly maintain the radiation pattern of the electron beam emitted in the radiation pattern as described above. Therefore, a dipole antenna for solving the above problems will be described below.

FIG. 4 is a plan view of a dipole antenna according to another embodiment, and FIG. 5 is a partially enlarged view of a region 'B' of FIG. The dipole antenna according to the present embodiment differs from the above-described antenna in that it includes an auxiliary circuit that realizes the same distance between the feeding pattern and each radiation pattern pair as compared with the above-described antenna. Hereinafter, the differences will be mainly discussed.

4 and 5, the dipole antenna 200 includes an insulation sheet 10, at least two radiation patterns 102 and 104 provided on the first surface 12 of the insulation sheet 10, At least two feeding patterns 252 and 262 provided on the second surface 14 of the insulating sheet 10 and electrically connected to the radiation pattern pairs 102 and 104 through the insulating sheet 10, An auxiliary circuit 50 for realizing distances between the power feeding patterns 252 and 262 and the individual radiation patterns 110, 120, 130 and 140 constituting the pair of radiation patterns 102 and 104, .

Specifically, the dipole antenna 200 includes a first radiation pattern pair 102 and a second radiation pattern pair 104 provided perpendicularly to the first surface 12 of the insulating sheet 10, And a first feeding pattern 252 which is provided on a second surface 14 of the insulating sheet 10 and is electrically connected to the first radiation pattern pair 102 and the second radiation pattern pair 104 through the insulating sheet 10, And a second feed pattern 262. The second feed pattern 262 may be formed of a material having a high dielectric constant. At least two pairs of radiation patterns 102 and 104 and the feed patterns 252 and 262 and the feeding portion B have been described in the above-described embodiment, and thus a repetitive description thereof will be omitted.

The dipole antenna 200 according to the present embodiment includes at least two pairs of radiation patterns 102 and 104 and power to individual radiation patterns 110, 120, 130, and 140 constituting the pair of radiation patterns 102 and 104 An auxiliary circuit (252, 262) is provided to supply power to the individual radiation patterns (110, 120, 130, 140) by the feeding patterns (252, 262) 50). The power supply patterns 252 and 262 are connected to the power supply patterns 252 and 262. The power supply patterns 252 and 262 are used to supply power to the individual radiation patterns 110, (110, 120, 130, 140) constituting the pattern pair (102, 104).

As described above, in the case of the power supply pattern having the first connection hole, that is, the means for avoiding interference with the other power supply pattern, when the power is supplied in the individual radiation pattern forming the radiation pattern pair by the power supply pattern, The distance from the pattern is different. Therefore, in this embodiment, the auxiliary circuit is provided in the first feeding hole, that is, the feeding pattern including means for avoiding interference with the other feeding pattern, so that the distance from the individual radiation pattern is kept the same.

6 is a cross-sectional view taken along a line VI-VI in Fig.

Referring to FIG. 6, the second feed pattern 262 includes a pair of connection holes 20 and 22 to avoid interference with the first feed pattern 252. That is, the second feeding pattern 262 is formed on the second surface 14 through the insulating sheet 10 through the first connection hole 20, passes through the first feeding pattern 252, And is formed on the first surface 12 through the hole 22 and connected to the fourth radiation pattern 140. In this case, the distance from the second through hole 260 of the second feeding pattern 262 to the end of the fourth radiation pattern 140 is set to 'L ₃ + L ₁ + 2T ', and it is necessary to increase the path length to the second radiation pattern by' 2T '.

The auxiliary circuit 50 includes a pair of auxiliary holes 40, which are provided on the opposite sides of the connection holes 20 and 22 with respect to the through hole 260, , 42). For example, when the connection holes 20 and 22 are provided in the second feeding pattern 262, the auxiliary circuit 50 may connect the second feeding pattern 262 with the second through- And a pair of auxiliary holes (40, 42) provided on the opposite sides of the connection holes (20, 22).

6, a pair of auxiliary holes 40 and 42 are formed on the opposite side of the connection holes 20 and 22 along the second through hole 260 along the second feed pattern 262, And the second feeding pattern 262 can be disposed through the auxiliary holes 40 and 42. [ In this case, the increase is much due to the second through hole 260, the second distance is also the secondary holes of the pair of ends to the radiation pattern (120) (40, 42) in the '2T''L ₃ + L ₁ + 2T ', which is equal to the distance to the end of the fourth radiation pattern 140. As a result, when power is supplied to the second radiation pattern pair 104 by the second feeding pattern 262, the length of the path connected to each radiation pattern 120, 140 constituting the second radiation pattern pair 104 The phase difference can be prevented from being supplied to the power supplied to each of the radiation patterns 120 and 140. This makes it possible to uniformly maintain the radiation pattern of the electron beam emitted from the radiation pattern. The auxiliary holes 40 and 42 may be formed at any position of the second feed pattern 262 connecting the second through hole 260 and the second radiation pattern 120. Preferably, And is provided symmetrically on the second feeding pattern 262 in the connection holes 20 and 22 around the hole 260.

According to the above-described embodiment, when a connection hole for avoiding interference between the power feeding patterns is provided, auxiliary holes having the same structure as the connection hole are further provided in the power supply pattern provided with the connection hole, So that the phase difference of the power is prevented. In order to manufacture the dipole antenna having the above-described structure, a process of forming a connection hole to avoid interference and a process of forming an auxiliary hole are further required. Particularly, since the connection hole and the auxiliary hole are formed to penetrate the insulating sheet, it can take a lot of time and cost depending on the process. Hereinafter, another embodiment of the auxiliary circuit will be described in order to solve the above inconvenience.

FIG. 7 is a plan view of a dipole antenna according to another embodiment, and FIG. 8 is a partially enlarged view of the 'C' region of FIG.

7 and 8, the insulation sheet 10 of the dipole antenna 300, at least two pairs of radiation patterns 102 and 104, the feed patterns 352 and 362, So that repetitive description will be omitted. Hereinafter, it is assumed that a connection hole is provided in the second feeding pattern 362.

 The auxiliary circuit 60 may include a bypass circuit 62 provided on the opposite side of the connection holes 20 and 22 with the second through hole 360 as a center. In this case, the bypass circuit 62 may be provided on the first surface 12 on which the radiation patterns 110, 120, 130, 140 are formed. 4 to 6, the bypass circuit 62 of the auxiliary circuit 60 includes a first surface (a first surface) on which the radiation patterns 110, 120, 130, and 140 are formed 12. Therefore, it is not necessary to form a hole or an auxiliary hole, and the bypass circuit 62 can be easily formed when the power supply patterns 352 and 362 are formed, thereby reducing the manufacturing process.

Here, the total length of the bypass circuit 62 is determined to be equal to the sum of the distance twice the thickness of the insulating sheet 10 and the distance between the connection holes 20, 22. That is, the total length of the bypass circuit 62 is determined to be the same as the distance elongated due to the connection holes 20, 22. For example, the total length of the bypass circuit 62 in FIGS. 7 and 8 corresponds to 2 * L ₅ + L ₆ , and the total length corresponds to twice the thickness of the insulating sheet 10, , 22), that is, 'L ₄ + 2 * T'. As a result, the distance between the second feeding pattern 362 and the individual radiation patterns 130 and 140 forming the second radiation pattern pair 104 is maintained to be the same by the bypass circuit 62, . In the present embodiment, the bypass circuit 62 is shown as a pattern bent at right angles, but this is merely an example and can be implemented in a curved form as well.

Hereinafter, the pattern of the beam by the dipole antennas 200 and 300 having the auxiliary circuit will be described. Theoretically, the beam emitted from the antenna travels in a direction perpendicular to the antenna. However, the pattern of the beam emitted from the actual antenna is shifted by a predetermined angle? In the vertical direction. The angle of rotation (θ) is changed due to various factors including the phase difference of power supplied in each radiation pattern as described above. The smaller the twist angle [theta] is, the more advantageous for transmission and reception of the antenna, and the allowable value can be determined according to the manufacturer's standard, customer's demand, and the like.

Table 1 below shows the result of actually measuring the twist angle in a predetermined frequency band by setting the maximum allowable value of the twist angle? To 3 degrees. In the following Table 1, 'Comparative Example' is defined as an antenna having no auxiliary circuit, and 'Embodiment' is defined as an antenna having an auxiliary circuit according to the present embodiment.

Frequency (GHz) 1.71 1.78 1.85 1.88 1.92 1.99 2.10 2.17 Comparative Example 2.56 2.41 2.62 2.92 2.68 3.03 3.12 2.67 Example 1.01 1.85 0.44 1.05 0.73 0.63 0.18 1.09

Referring to Table 1, it can be seen that in the comparative example having no auxiliary circuit, the average of the twist angles corresponds to approximately 2.75, which is very close to the allowable value of 3 degrees. Furthermore, it can be seen that when the frequencies are 1.99 GHz and 2.10 GHz, the torsional angles exceed the permissible values of 3.03 and 3.12, respectively.

On the other hand, in the case of the embodiment having the auxiliary circuit, the twist angle is approximately 0.87, which is relatively low compared to the comparative example. Also, in the case of the embodiment, it can be seen that the twist angle in the entire frequency band is less than the allowable value. Accordingly, in the case of the antenna having the auxiliary circuit according to the present embodiment, the twist angle of the emitted beam can be minimized, and the beam pattern can be made uniform.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. You can do it. It is therefore to be understood that the modified embodiments are included in the technical scope of the present invention if they basically include elements of the claims of the present invention.

20, 22 ... connection holes 40, 42 ... auxiliary holes
50, 60 ... auxiliary circuit 62 ... bypass circuit
102 ... first radiation pattern pair 104 ... second radiation pattern pair
110 ... first radiation pattern 120 ... second radiation pattern
130 ... third radiation pattern 140 ... fourth radiation pattern
152, 252, 352 ... First feeding patterns 162, 262, 363 ... Second feeding pattern

Claims (14)

Insulating sheet;
At least two radiation patterns provided on a first surface of the insulating sheet;
At least two feeding patterns provided on a second surface of the insulating sheet and electrically connected to the pair of radiation patterns through the insulating sheet; And
And an auxiliary circuit for realizing distances between the power supply pattern and individual radiation patterns forming each pair of radiation patterns. The method according to claim 1,
Wherein at least one of the two or more power supply patterns connected to the radiation pattern pair is connected through a pair of connection holes passing through the insulation sheet to avoid interference with the other radiation pattern. 3. The method of claim 2,
Wherein the power supply pattern provided with the connection hole is connected to each of the radiation pattern pairs through a through hole of the insulating sheet and the auxiliary circuit includes a pair of auxiliary holes provided on the opposite side of the connection hole, And a dipole antenna. The method of claim 3,
Wherein the auxiliary hole is symmetrically provided in the connection hole around the through hole. 3. The method of claim 2,
The power supply pattern provided with the connection holes is connected to each of the radiation pattern pairs through the through holes of the insulating sheet and the auxiliary circuit is provided on the opposite side of the connection holes with respect to the through holes And the dipole antenna. 6. The method of claim 5,
Wherein the bypass circuit is provided on the first surface on which the radiation pattern is formed. 6. The method of claim 5,
Wherein a total length of the bypass circuit is equal to a sum of a distance twice the thickness of the insulating sheet and a distance between the pair of connection holes. Insulating sheet;
A pair of first radiation pattern and a pair of second radiation pattern provided perpendicularly to the first surface of the insulating sheet;
A first feeding pattern and a second feeding pattern provided on a second surface of the insulating sheet and electrically connected to the first and second radiation pattern pairs through the insulating sheet;
And an auxiliary circuit which realizes the same distance between each of the power feeding patterns and the individual radiation pattern forming each pair of radiation patterns. 9. The method of claim 8,
Wherein the second feeding pattern is connected through a pair of connection holes passing through the insulating sheet to avoid interference with the first feeding pattern. 10. The method of claim 9,
The second feeding pattern is connected to each of the second radiation pattern pairs through the through holes of the insulating sheet,
Wherein the auxiliary circuit includes a pair of auxiliary holes provided in the second feeding pattern on the opposite side of the connection hole with respect to the through hole. 11. The method of claim 10,
Wherein the auxiliary hole is symmetrically provided in the connection hole around the through hole. 10. The method of claim 9,
The second feeding pattern is connected to each of the second radiation pattern pairs through the through holes of the insulating sheet,
Wherein the auxiliary circuit includes a bypass circuit provided on the opposite side of the connection hole along the second feed pattern with the through hole as a center. 13. The method of claim 12,
And the bypass circuit is provided on the first surface. 13. The method of claim 12,
Wherein a total length of the bypass circuit is equal to a sum of a distance twice the thickness of the insulating sheet and a distance between the connection holes.

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