KR20140102974A - A broadband plannar Quasi-Yagi antenna - Google Patents

Abstract

The present invention relates to a broadband planar quasi-yagi antenna used for a mobile communications base station and terrestrial digital broadcast reception and, more specifically, to a broadband planar quasi-yagi antenna comprising: a dielectric substrate; a co-planar strip which is disposed on one surface of the dielectric substrate and formed with in two conductive strips having a central portion spaced apart in a predetermined distance; a dipole which is fed to the co-planar strip; a microstrip line which is mounted in the co-planar strip and is fed to the co-planar strip having a short-circuited end portion; and a rectangular director element which is spaced apart on the upper part of the dipole by a certain wavelength of a resonant frequency of the dipole.

Description

[0001] The present invention relates to a broadband planar quasi-Yagi antenna,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a broadband plane quasi-yagi antenna used for mobile communication base stations or terrestrial digital broadcasting receivers, and more particularly to a quasi-yagi antenna having wide bandwidth and directivity, A quasi-yagi antenna comprising a dipole, a ground plane reflector, and a dipper.

Terrestrial digital TV (DTV) provides more than twice the quality of analog TV and provides a variety of application services. As a result, Korea has become a 100% digital broadcasting service in 2013. State.

 Currently, the frequency band allocated for DTV is 470 ~ 806 MHz, and the frequency range is very wide. Therefore, the receiving antenna should be designed to have broadband characteristics.

The first document (CA Balanis, Antenna theory : Analysis and According to the design , 3rd ed., Hoboken, NJ: Wiley, 2005.), antennas with wideband and proper gain and directivity are typical of log periodic antennas (LPAs) It is not easy to construct an array antenna.

The second paper (N. Kaneda, WR Deal, Y. Qian, R. Waterhouse, and T. Itoh, "A broadband quasi-Yagi antenna," IEEE Trans . Antennas Propagate . , vol. 50, no. 8, pp. 1158-1160, Aug. 2002.), a quasi-Yagi antenna (QYA) fabricated by a printing technique on a flat substrate uses a ground plane edge as a reflector and a dipole projector as a coplanar strip (CPS) line And directivity can be obtained by placing a director at an appropriate distance.

QYA is small and has a relatively wide bandwidth with appropriate gain and front-to-back ratio (FBR), and is used in various fields such as radar, direction-finding antenna, and antenna for RF transceiver.

Vol. 45, no. 24, pp. 1207-1209, Nov. 2009), and the third paper (K. Han, Y. Park, and I. Park, "Broandband CPS-fed Yagi-Uda antenna," Electron Lett. There is a method of broadband matching a microstrip (MS) line or a coplanar waveguide (CPW), which is a feeder line, with a tapered line, but the length of the feeder line must be increased by a matching circuit .

Recently, a study has been reported on feeding QYA by a CPW-to-CPS conversion structure without a separate balun circuit.

However, while the structure is simple, the radiation pattern has a disadvantage that it tends to be asymmetrical with respect to the array axis, and the bandwidth is 44% and the gain is 3.4-7.4 dBi.

Since the method of constructing the broadband balun between MS and CPS on the same plane has been proposed, many studies on the design and application of broadband QYA for X-band (8-12GHz) using various feeding methods have been published, The design results for the band (1-2 GHz) have also been reported.

Another way is to make the balance between the MS and the CPS on the CPS so that the broadband matching characteristic can be obtained without requiring a separate space for the balun on the substrate.

In this case, the MS feeds the dipole projector across the CPS terminated with a short circuit, and the MS is terminated with an open circuit at about a quarter wavelength length from the feed point.

The fourth article (RL Li, T. Wu, B. Pan, K. Lim, J. Laskar, and MM Tentzeris, "Equivalent-circuit analysis of a broadband printed dipole with adjusted integrated balun and an array for base station applications, IEEE Trans. Antennas Propagat ., Vol. 57, no. 7, pp. 2180-2184, Jul. 2009.), a recent study on broadband planar dipole antennas fed to MS has reported that the implementation of wideband impedance matching by adjusting the feed point location on the CPS has been reported.

According to the results of the study on QYA (the second article mentioned above), when the broadband matching characteristic (about 48%) is obtained, the gain is lowered to 3-5 dBi and conversely the gain is increased by 2 dB (5-7 dBi) (About 17%), it is difficult to implement an antenna having characteristics that satisfy both a wideband and a high gain.

In summary, the results of the broadband QYA studied up to now have a disadvantage in that the bandwidth is about 45%, which is relatively wide, and the minimum gain in the band is relatively small, about 3 dBi.

First document: C.A. Balanis, Antenna theory: Analysis and design, 3rd ed., Hoboken, NJ: Wiley, 2005. The second paper: N. Kaneda, W. R. Deal, Y. Qian, R. Waterhouse, and T. Itoh, "A broadband quasi-Yagi antenna," IEEE Trans. Antennas Propagat., Vol. 50, no. 8, pp. 1158-1160, Aug. 2002. Third paper: K. Han, Y. Park, and I. Park, "Broadband CPS-fed Yagi-Uda antenna," Electron Lett., Vol. 45, no. 24, pp. 1207-209, Nov. 2009. 4th article: RL Li, T. Wu, B. Pan, K. Lim, J. Laskar, and MM Tentzeris, "Equivalent-circuit analysis of a broadband printed dipole with adjusted integrated balun and an array for base station applications, IEEE Trans. Antennas Propagat., Vol. 57, no. 7, pp. 2180-2184, Jul. 2009.

SUMMARY OF THE INVENTION It is an object of the present invention to provide a broadband planar quasi-yagi antenna having a wider bandwidth and a proper and even gain.

It is another object of the present invention to provide a broadband plane quasi-yagi antenna for designing and miniaturizing an antenna for a mobile communication base station or a terrestrial DTV receiving antenna with a three-element QYA.

It is still another object of the present invention to provide a broadband device having a broadband characteristic (bandwidth of about 53% or more or impedance bandwidth ratio of 1.72: 1 or more) having a VSWR < 2 within a DTV band (470 to 806 MHz) dBi &lt; / RTI &gt; in a directional broadband plane quasi-yagi antenna.

It is another object of the present invention to provide a method of manufacturing a flat plane dipole antenna which is fed by a coplanar strip and which is embedded in a coplanar strip and fed with a shorted end microstrip to eliminate the need for a separate space for the balun, and a quasi-yagi antenna.

It is also an object of the present invention to provide a broadband planar quasi-linear array antenna which adjusts the width, length, element-to-element spacing and the like of each element and deforms the dipole and reflector into a half bow- And a quasi-yagi antenna.

In order to achieve the above object, a broadband planar quasi-yagi antenna according to the present invention comprises a dielectric substrate and a dielectric layer formed on one surface of the dielectric substrate and having a plurality of conductor strips, A planar strip, a dipole fed to the coplanar strip, and a microstrip line embedded in the coplanar strip, the end of which is short-circuited to feed the coplanar strip, and a rectangle spaced apart by a certain wavelength of the resonant frequency of the dipole Of the first waveguide.

Further, the broadband plane quasi-yagi antenna of the present invention is further characterized by a ground plane reflector located under the dipole and connected to the coplanar strip and the microstrip line.

 In addition, the broadband plane quasi-yagi antenna of the present invention further includes a second waveguide located above the first waveguide, the second waveguide being longer than the length of the first waveguide.

In addition, the broadband plane quasi-yagi antenna of the present invention is characterized in that the dipole and the ground plane reflector have a semi-bow-tie shape in the direction opposite to each other.

In particular, the wideband plane quasi-yagi antenna of the present invention is characterized in that impedance matching between the dipole and the coplanar strip is obtained by adjusting the feed position of the microscript line.

The wideband planar quasi-yagi antenna of the present invention is advantageous in that it has a wider bandwidth and an appropriate and uniform gain as compared with the conventional antenna.

In addition, the broadband planar quasi-yagi antenna of the present invention is fed by a planar dipole into a coplanar strip and fed into a microstrip with a terminated short circuit for balun There is an advantage that a space of the display device is not required.

In addition, the broadband planar quasi-yagi antenna of the present invention can adjust the width, length, and space between elements of each device, and deform the dipole and reflector into a half bow-tie shape, .

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a broadband plane quasi-yagi for a mobile communication base station according to an embodiment of the present invention; FIG.
FIG. 2 is a four-antenna structure view of a wideband plane quasi-yagi for a mobile communication base station according to an embodiment of the present invention; FIG.
3 is a reflection coefficient plot of a broadband plane quasi-yagi dipole projector D _o for a mobile communication base station according to an embodiment of the present invention.
Fig. 4 is a diagram showing the influence of proximity rejection (D ₁ ). Fig. 4 (a) is a reflection coefficient diagram when the length L ₁ (b) is different from the width w ₁ .
FIG. 5 is a graph showing the effect of the reflector R _o and the waveguide D _{2 in} a broadband plane quasi-yagi antenna for a mobile communication base station according to an embodiment of the present invention. FIG. 5 (a) Fig.
FIG. 6 is a half-bow type structure of a broadband plane quasi-yagi for receiving terrestrial digital broadcasting according to an embodiment of the present invention; FIG.
FIG. 7 is a diagram illustrating four antenna structures of a wideband plane quasi-yagi for receiving terrestrial digital broadcasting according to an embodiment of the present invention; FIG.
FIG. 8 is a reflection coefficient diagram of a broadband plane quasi-yagi dipole projector + waveguide (D ₀ + D 1) according to an embodiment of the present invention.
9 is a graph illustrating the reflection coefficient of a quasi-yagi dipole + waveguide + reflector ('D ₀ + D ₁ + R ₀ ') of a broadband plane quasi-yagi receiving terrestrial digital broadcasting according to an embodiment of the present invention and Fig.
10 is a diagram illustrating the reflection coefficient and gain of a quasi-yagi broadband bow tie type for a mobile communication base station according to an embodiment of the present invention.
(Where h ₀ = 40, L ₀ = 220, h _r = 50 and L _r = 240)

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that a detailed description of related art or configuration may unnecessarily obscure the gist of the present invention, The same reference numerals and the same terminology will be used for the same parts regardless of the order of the drawings, and the terms described below are terms defined in consideration of the functions of the present invention. These terms are used for the purpose of the user, The definition should be based on the description throughout this specification which describes a broadband planar quasi-yagi antenna of the present invention.

1 is a structural diagram of a broadband plane quasi-yagi antenna for a mobile communication base station according to a temporal example of the present invention.

MS is formed on the front side, and QYA and CPS that feed it are located on the rear surface where the ground plane exists.

A dipole driver D ₀ with a proximate parasitic director D ₁ is fed to the CPS and can adjust the feed point location d _f to achieve wide band matching with an MS having a characteristic impedance of 50 ohms.

Implement balancing between the MS and the CPS for QYA feeding on the CPS, but by balancing the microstrip termination.

As shown in FIG. 2 (a), it is difficult to obtain a sufficiently wide bandwidth when the projector of QYA is constituted by a single dipole antenna. Therefore, the parasitic element D ₁ is located in the proximity region (distance d ₁ ) .

In addition, it is the structure of FIG. 2 (c) that the ground plane is made up of the reflector R ₀ , and the structure of FIG. 2 (d) finally adds the waveguide D ₂ .

First, FIG. 3 shows the reflection coefficient characteristic when a dipole antenna composed only of the projector D ₀ is matched with the feed line.

Each parameter values _{W = L = 90, d r} = 36, L r = 2w s = 20, w r = 15, L 0 = 72, w 0 = 7.5, g s = 0.7, w f = 3, d f = 25, x _f = 5 and the unit is mm.

The characteristic impedance of the microstrip and the slot line feeding the dipole are about 50 ohms and 100 ohms, respectively, and impedance matching between the dipole and the feeder line can be obtained by adjusting the position (d _f ) of the feed point.

At a resonance frequency (1.68 GHz), the gain is close to 2.0 dBi, which is close to the typical dipole gain (about 2.2 dBi) in the band with a reflection coefficient of | S ₁₁ | <-10 dB at 1.53-1.88 GHz (about 20.5%).

Because bandwidth is limited only by the dipole antenna (D _0), the present invention improves the bandwidth in a manner that an additional wave guide the wave director (D ₁₎ of the right size to very close to the feed zone dipole (d ₁ = 2-3 mm) .

In a typical QYA design, the distance d ₁ between the waveguide and the projector is about 0.1-0.2 wavelength at the resonance frequency, while the interval d ₁ in the present invention is about 0.01-0.02 wavelength at the resonance frequency of the dipole (1.68 GHz) .

The broadband characteristics suitable for the desired band (1.75-2.7 GHz) can be obtained by adjusting the width (w ₁ ) and length (L ₁ ) of the waveguide by fixing the interval d _{1 =} 2 mm so that good broadband characteristics can be observed.

In FIG. 4 (a), when the length L ₁ of the waveguide is increased, the matching characteristics of the high frequency band can be improved and the lower cutoff frequency is gradually increased.

At this time, L _r = 2w _s + g _s is composed of only the projector and the waveguide without the reflector.

As shown in FIG. 4 (b), when the width w ₁ is increased, the lower cutoff frequency is slightly increased, and when w ₁ > 9, the wideband matching characteristic including the desired band can be obtained.

If the width and length of the near-field waveguide (D ₁ ) are fixed to w ₁ = 11 and L _r = 29 to have broadband characteristics, the -10 dB band is 1.59-2.95 GHz and the required frequency band (1.75-2.7 GHz) And the bandwidth is about 60%, which is about 10% better than the existing broadband QYA.

As shown in FIG. 5 (a) ['D ₀ + D ₁ '], the higher the frequency, the better the directionality in the array axis direction by the waveguide. 4 dBi, but the low-frequency band is slightly larger than the target of 4.5 dBi.

If the reflector R ₀ of L _r = W is added [denoted as 'R ₀ + D ₀ + D ₁ '], the gain of the low frequency band is improved without a large change in the impedance matching characteristic.

Further, when the adder [denoted by R ₀ + D ₀ + D ₁ + D ₂ ') further adds a waveguide D ₂ (with d ₂ = 22.5, L ₂ = 32 and w ₂ = 3.3) The gain is maintained over 4.5 dBi and the impedance matching characteristic is optimized to satisfy the target characteristic since the -10 dB band is 1.55-2.77 GHz (56.5%) and the desired band is included.

Therefore, the reflector improves the gain of the low frequency band and the waveguide D ₂ improves the gain of the whole frequency band. It can be seen that the improvement amount increases from the low frequency to the high frequency.

The optimized QYA band was broadband at 1.55-2.77 GHz (about 56.5%) and the gain was 4.67-5.66 dBi in the band, which was improved by 1.5 dB over the gain (3-5 dBi) of the existing wideband QYA [2] And shows an even gain distribution.

Therefore, the fabricated wideband QYA is expected to be suitable for application as an antenna for a small power repeater that integrates various mobile communication (PCS, IMT200, LTE) and wireless services (WiBro, WLAN, Bluetooth, WiMAX) It can be easily configured as a wideband high gain array antenna by adding a power feeding circuit and can be utilized as a mobile communication base station antenna.

6 is a diagram illustrating a broadband plane quasi-yagi antenna for receiving terrestrial digital broadcasting, in which dipoles and reflectors are of a semi-bow type.

A dipole (D ₀ ), a ground plane reflector (R ₀ ), and a waveguide (D ₁ ) that are fed to the coplanar strip are printed on one side of the dielectric substrate.

The feed microstrip line is embedded in the coplanar strip to reduce the extra space for the balun and the termination is short-circuited.

In order to achieve broadband characteristics, the waveguide is located in the region close to the dipole, and the dipole and the reflector are of a semi-bow-tie type (or V type) in order to miniaturize the antenna.

An antenna satisfying the conditions of VSWR <2 and gain> 3.5 dBi in the band is designed on the FR4 board (relative dielectric constant 4.4, thickness 1.6 mm, loss tangent 0.025) in order to be suitable for the operation of the frequency band for terrestrial DTV (470-806 MHz) do.

However, the characteristic impedance of the microstrip line is 75 ohm (w _f = 1.38) so that it matches the port impedance of DTV 75 ohm.

FIG. 7 shows a process of designing the antenna of the proposed structure, and the feeding microstrip line is located on the other side as shown in FIG.

Figure 7 (a) shows feeding the dipole (D ₀ ) connected to the coplanar strip to a 75-ohm microstrip line (for convenience 'D ₀ ') and Figure 7 ₁ ) Wide rectangle patch type waveguide (D ₁ ) is placed in the region very close to the dipole ('D ₀ + D ₁ ' case) compared with the typical waveguide. y direction) can be obtained.

Figure 7 (c) is a ground plane to a portion of the reflector (R ₀₎ at the right distance from the dipole (also in case _{'D 0 + D 1 + R} 0') gain improved so as to have a gain distribution uniform in the entire desired frequency band as a Can be obtained.

FIG. 7 (d) shows a dipole-and-tie shape of the dipole and the reflector to reduce the size of the antenna (referred to as 'D ₀ ^BT + D ₁ + R ₀ ^BT ').

The planar dipole of Fig. 7 (a) is connected to the shorted terminated coplanar strip line, and the coplanar strip is fed by a microstrip line of 75 ohm characteristic impedance.

Impedance matching between the feed line and the dipole can be obtained by adjusting the feed position d _f of the short-circuited microstrip line.

The resonance frequency is determined by the length L ₀ of the dipole and the resonance frequency is slightly increased when the proximity waveguide is added as in the case of 'D ₀ + D ₁ ' in FIG. 7 (b) 470 to 806 MHz), which is slightly lower than the lower limit frequency (470 MHz).

It is shown in Figure 8 with 'D _0', and the reflection coefficient characteristics when L ₀ = 270 mm, the parameter values are L = 200, W = 300, t = 1.6, w f = 1.38, x f = 5, g s = 2, w _s = 20, w ₀ = 10, d ₀ = 110, d _f = 100 and the unit is mm.

The resonance frequency is 452 MHz and the VSWR <2 band is 425 ~ 502 MHz, which shows the characteristics of a typical dipole antenna with a bandwidth of about 16.6%.

The reason why the feed point (d _f = 100) where the impedance matching is observed is close to the dipole is that the resonance impedance of the dipole is close to the characteristic impedance (75 ohms) of the feed line.

The length of the dipole (L ₀₎ of about 0.41λ ₀ at the resonance frequency 452 MHz; is equivalent to (λ ₀ free-space wavelength).

Close to, (a wavelength of a coplanar strip line λ _g) characteristic of a coplanar strip line impedance is about 127 ohms and a coplanar 0.25λ _g on the length _{(d 0 + w 0 = 120} ) of the slot between the strip 490 MHz do.

Since the desired broadband characteristics can not be obtained with only the dipole, a wide waveguide (D ₁ ) is added to the region close to the dipole as shown in Fig. 7 (b).

The feed point impedance of the antenna is changed by the proximity waveguide and the broadband matching characteristic is obtained while varying the feed position d _f along with the position d ₁ , width w ₁ and length L ₁ of the waveguide .

8, the data in the case of D ₀ + D ₁ is a reflection coefficient characteristic when a waveguide having a width w ₁ = 60 and a length L ₁ = 105 is placed at a distance d ₁ = 4 from the dipole.

If the if 'D _0' that only dipole and the location of the feed point is the same d _f = 100 band is 444 ~ 555 MHz (bandwidth of about 22.2%) is widened to, but improved matching characteristics most DTV frequency bands (555-806 MHz), the matching characteristic should be further improved.

As shown in FIG. 8, the band 444 satisfying VSWR < 2 when d _f = 70 is gradually improved as the feed point d _f is decreased when the feed position is reduced in the same state. To 890 MHz) includes the desired band (470 to 806 MHz), and the bandwidth (444 MHz) is 66.47% and the impedance bandwidth ratio is close to 2: 1 .

By the proximity waveguide, the antenna has improved directivity in the arrangement axis direction (y direction), and the gain is maintained at 3.3 dBi or more in the DTV band when d _f = 70, as 3.33 ~ 4.24 dBi.

In the case of 'D ₀ + D ₁ ', the in-band gain is maintained at least 3.3 dBi, but when the reflector is added as shown in FIG. 7 (c), the gain is improved and a uniform gain distribution in the band can be obtained.

FIG. 9 is a characteristic when a reflector having a width w _r = 10 and a length L _r = W = 300 is added, and the characteristic of the case of 'D ₀ + D ₁ ' is also presented for reference.

As shown in FIG. 9, the addition of the reflector has no significant effect on the impedance characteristic as compared to the case of D ₀ + D ₁ .

However, it can be seen that the antenna gain improves remarkably by more than 0.5 dB in the low frequency band.

At this time, the frequency band of VSWR < 2 is 463 to 888 MHz, which includes the target band and exhibits excellent broadband characteristics with a bandwidth of 62.9%.

The gain in the DTV band is maintained over 3.8 dBi (3.83 ~ 4.98 dBi) and the stable gain distribution is not large.

The antenna parameters are optimized to some extent and the optimized parameter values are as shown in Table 1.

The optimized antenna parameters (in the case of 'D ₀ + D ₁ + R ₀ ') parameter  Value (mm)  parameter  Value (mm) L 200 w ₀ 10 W 300 d ₀ 110 t 1.6 d _f 100 W _f 1.4 W ₁ 60 X _f 5 L ₁ 105 g _s 2 d ₁ 70 w _s 20 w _r 10 L ₀ 270 L _r 300

When prior hayeoteul width to optimize the antenna in the structure of 7 (c) is also configured, the device of the QYA a fixed strip, the overall size of the antenna ground plane width of the reflector (L _r = 300) and the dipole width (L ₀ = 270 It is desirable to reduce the size of the antenna so as not to significantly affect the performance of the antenna.

For the miniaturization, the method adopted in the present invention is to transform the dipole and the reflector into the semi-bow-tie type as shown in Fig. 6 or Fig. 7 (d).

The width of the dipole and the reflector at the portion (x = ± w _s / 2) facing the feeder line does not change to w ₀ = w _{r =} 10, but at the end, w ₀ + h ₀ and w _r + h _r linearly increases.

By increasing the bow-tie width (h ₀ and h _r ), the path of the current in the conductor strip is extended, so that the size of the antenna (L ₀ and L _r ) can be reduced.

Figure 10 is a reflector (R ₀₎ only, while leaving intact the dipole half bow - When Thai-type strain as _{(h 0 = 40, L 0} = 220, h r = 0, L r = 300) and the reflective airway half bow- (H ₀ = h _r = 0) in the case of deforming to a tie shape (h ₀ = 40, L ₀ = 220, h _r = 50, L _r = 240) Table 2 summarizes the results.

As can be seen from the results of FIG. 10 and Table 2, although the antenna size (L _r = 240) of the semi-bow-tie type was reduced by 20% compared to the size without modification (L _r = 300) Bandwidth and a stable gain distribution.

A uniform gain distribution with an impedance bandwidth ratio of about 2: 1 and a gain variation of less than 0.32 dB from 4.31 dBi is an excellent property that can be implemented in LPA and is hardly achievable in most of the previous studies on QYA.

Comparison of QYA performance of semi-bow tie type no. L ₀ h ₀ L _r h _r band * gain ** One 270 0 300 0 463-888 3.83-4.98 2 220 40 300 0 472 to 862 3.98-4.66 3 220 40 240 50 437-860 3.99 to 4.62

* frequency band for VSWR < 2: MHz

** gain over DTV band (470806 MHz): dBi

In the case of VSWR <2 band, 450 ~ 848 MHz gain was more than 4.1 dBi and front / rear ratio was more than 10.4 dB.

The quasi-yagi antenna for receiving terrestrial digital broadcasting according to the present invention can be applied as a broadband directional antenna for various purposes due to its easy frequency conversion design and is promising for use as an element antenna of a high gain array antenna .

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. It is not.

Claims (5)

The dielectric substrate
A coplanar strip formed on one surface of the dielectric substrate and formed of two conductor strips having a central portion spaced apart by a predetermined distance;
A dipole that is fed to the coplanar strip;
A microstrip line embedded in the coplanar strip and shorted in termination to feed the coplanar strip;
A first rectangular waveguide having a predetermined wavelength of the resonance frequency of the dipole on the dipole;
Wherein the broadband plane quasi-yagic antenna comprises:
The method according to claim 1,
And a ground plane reflector located below the dipole and connected to the coplanar strip and the microstrip line,
Wherein the antenna comprises a first antenna and a second antenna.
3. The method of claim 2,
A second waveguide located above the first waveguide and longer than the length of the first waveguide;
Wherein the antenna comprises a first antenna and a second antenna.
3. The method of claim 2,
Characterized in that the dipole and the ground plane reflector are of a semi-bow-tie type in the direction opposite to each other
Broadband plane quasi - yagi antenna.
5. The method according to any one of claims 1 to 4,
Wherein impedance matching between the dipole and the coplanar strip is obtained by adjusting a feed position of the micro-
Broadband plane quasi - yagi antenna.

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