KR200348650Y1 - A high gain microstrip antenna by using Yagi structure - Google Patents

Abstract

The present invention relates to a high-gain antenna used in a wireless communication system. More specifically, the front and rear ratio is excellent by constructing a Yagi antenna pattern on a microstrip substrate and suppressing the side lobe with a reflecting plate bent at the front of the lower part. The present invention relates to a high gain microstrip antenna using a Yagi antenna structure having high directivity and gain in one direction and at the same time having wide electrical characteristics.

Generally, a dipole antenna, a yagi antenna, and a microstrip antenna are mainly used in a wireless communication system, and in particular, a microstrip antenna is a flat antenna using a pattern implemented on a circuit board, and is easily manufactured, changed in shape, and miniaturized and lightweight. Do. However, since the microstrip antenna has a narrow frequency bandwidth of several percent or less and low gain, when designing an array antenna to obtain high gain, accurate design conditions between elements are required, and the size of the antenna increases.

In order to solve the above problems, the present invention constructs a Yagi antenna pattern on the microstrip substrate and includes a reflecting plate bent at the front of the lower part to suppress side lobes, thereby providing excellent front and rear ratio, and having high directional and gain in one direction. Provided is a high gain microstrip antenna using a Yagi antenna structure having electrical characteristics.

In addition, by constructing the Yagi antenna pattern on the microstrip substrate, it is easy to increase the gain through the increase of the device while using a small area, and it is possible to miniaturize and lighten the structure, and the structure is simple, so that the cost reduction and uniformity of the mass production Has the effect of obtaining the characteristic.

Description

High gain microstrip antenna by using Yagi structure

The present invention relates to a high-gain antenna used in a wireless communication system. More specifically, the front and rear ratio is excellent by constructing a Yagi antenna pattern on a microstrip substrate and suppressing the side lobe with a reflecting plate bent at the front of the lower part. The present invention relates to a high gain microstrip antenna using a Yagi antenna structure having high directivity and gain in one direction and at the same time having wide electrical characteristics.

Generally, a dipole antenna, a yagi antenna, and a microstrip antenna are mainly used in a wireless communication system. In particular, the microstrip antenna is a planar antenna using a pattern implemented on a circuit board as shown in FIG. Processed with the ground plane 103 using one metal plate, and laminated the dielectric substrate 102 having a predetermined thickness thereon, and then implemented the shape of the patch 101 on the dielectric. Is possible.

However, since the microstrip antenna is a resonant antenna whose fundamental property is a narrow frequency bandwidth of less than several% and low gain, when designing an array antenna to obtain high gain, accurate design conditions between elements are required. There is a problem that increases.

Accordingly, the present invention is to solve the above problems, by constructing a Yagi antenna pattern on the microstrip substrate and having a reflector plate bent in the front of the lower side to suppress the side lobe, excellent front and rear ratio, high directivity and gain in one direction The present invention provides a high gain microstrip antenna using a Yagi antenna structure having a wideband electrical characteristic.

In addition, the present invention is easy to increase the gain through the increase of the device while using a small area by configuring the Yagi antenna pattern on the microstrip substrate, and can be miniaturized and lightweight, and the structure is simple, reducing the cost of mass production The present invention provides a high gain microstrip antenna using Yagi antenna structure capable of achieving uniform and uniform characteristics.

1 is a view showing the structure of a conventional general microstrip antenna.

Figure 2 is a perspective view of a high gain microstrip antenna using Yagi antenna structure according to the present invention.

Figure 3a is a rear view of a high gain microstrip antenna using Yagi antenna structure according to the present invention.

Figure 3b is a plan view of a high gain microstrip antenna using Yagi antenna structure according to the present invention.

Figure 3c is a side view of a high gain microstrip antenna using Yagi antenna structure according to the present invention.

4 is a view showing the voltage standing wave ratio of the high-gain microstrip antenna using the Yagi antenna structure according to the present invention.

5 is a view showing a radiation pattern of a high gain microstrip antenna using a Yagi antenna structure according to the present invention.

6 is a view showing an increase in the number of elements of the high-gain microstrip antenna using Yagi antenna structure according to the present invention.

※ Explanation of code for main part of drawing

101. Patch 102. Dielectric

103. Ground plane 201: Reflector

202. Choke 203. Microstrip Substrates

204. Copiers 205. Waveguides

206. Reflector 207. Ground plane

208. Microstrip tracks 209. First stub

210. 2nd stub 211. Feed connector

212. Feed point 213. Support means

In order to achieve the above object, the present invention, in a high-gain antenna used in a wireless communication system, a half-wave dipole structure formed on a microstrip substrate to excite electromagnetic waves generated by magnetic current to parasites. A copier 204; and a microstrip line 208 having a feed point 212 formed at one side and connected to the copier to transmit a signal; and matching the input impedance of the microstrip line with the input impedance. A first stub 209 formed at a predetermined position on the microstrip line; and a reflector 206 formed at the rear of the copier having a structure slightly longer than half wavelength to reflect back radiation of electromagnetic waves generated from the copier; and It is formed in front of the copier, and it recovers the electromagnetic waves reflected from the copier and the electromagnetic waves reflected from the reflector. Waveguide 205 having a structure slightly shorter than half wavelength to improve the gain through; and a ground plane 207 formed opposite to the reflector on the opposite side of the microstrip substrate to radiate impedance matching and electromagnetic waves into free space. And a second stub 210 formed adjacent to the ground plane on the opposite side of the microstrip substrate to improve impedance matching and bandwidth; and maintaining a height of a predetermined gap formed as an air layer under the microstrip substrate. A reflection plate 201 bent to have a high front-to-back ratio by reflecting electromagnetic waves radiated on the microstrip substrate and suppressing side lobes; and a choke 202 formed on the reflection plate to suppress electric beam tilt; and A power supply connector 211 connected to the power supply point to supply external power; And support means 213 for maintaining a predetermined gap between the microstrip substrate and the reflecting plate.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the following description, the same or corresponding members will be denoted by the same reference numerals and detailed description thereof will be omitted.

2 is a perspective view of a high gain microstrip antenna using a Yagi antenna structure according to the present invention, and FIGS. 3A to 3C are rear, top, and side views of the high gain microstrip antenna using the Yagi antenna structure according to the present invention, respectively. . As shown in FIG. 3A, a high-gain microstrip antenna using a Yagi antenna structure according to the present invention is a half formed to excite electromagnetic waves generated by magnetic current on parastrip elements on a microstrip substrate 203. A copier 204 having a wavelength dipole structure, a microstrip line 208 having a feed point 212 formed at one side thereof to transmit a signal connected to the copier, and having an input impedance matched therein, and an input impedance of the microstrip line The first stub 209 formed at a predetermined position on the microstrip line to match the and the reflector 206 formed at the rear of the copier having a structure slightly longer than half wavelength to reflect the back radiation of the electromagnetic waves generated from the copier. ), And formed in front of the copier, electromagnetic waves generated by the copier and reflected by the reflector At least one waveguide 205 having a structure slightly shorter than a half wavelength to improve gain through forward radiation, and maintaining a predetermined height formed by an air layer below the microstrip substrate and radiating on the microstrip substrate. The reflection plate 201 is bent to have a high front-to-back ratio by reflecting the electromagnetic wave and suppressing the side lobe, and a choke 202 formed on the reflection plate to suppress the electric beam tilt is provided.

At this time, the copier 204 is a half-wave dipole structure and in the embodiment of the present invention is a length of 0.45 λ to receive a signal from the microstrip line 208 that the input impedance is matched to 50 Ω to be copied to the free space The reflector 206 is slightly longer than half wavelength (0.53 lambda in this embodiment) and reflects back radiation of electromagnetic waves of the copier 204 at a distance of 0.18 lambda from the copier 204. In addition, the waveguide 205 is slightly shorter than the half wavelength (0.3 lambda in the embodiment of the present invention) to improve the gain by radiating forward the electromagnetic waves excited from the copier 204 and the reflector 206. do.

In addition, since the first stub 209 is formed at a predetermined position of the microstrip line 208 and has the same effect as connecting the capacitors in parallel so that the microstrip line 208 can match the impedance to 50 kHz . By changing the size and position of the stub with respect to the minute change of the microstrip line 208, it can be matched to a desired impedance and can have stable characteristics.

3B is a plan view of a high-gain microstrip antenna using a Yagi antenna structure according to the present invention, and is formed to face the reflector on the opposite side of the microstrip substrate so that a ground plane 207 radiates impedance matching and electromagnetic waves into free space. And a second stub 210 formed adjacent to the ground plane on the opposite side of the microstrip substrate to improve impedance matching and bandwidth, and a feed connector connected to the feed point 212 to supply external power. 211 is provided.

Figure 3c is a side view of a high-gain microstrip antenna using the Yagi antenna structure according to the present invention to configure the pattern of Yagi antenna on both sides of the microstrip substrate 203, bent to the slope of the lower portion of the microstrip substrate 203 The reflecting plate 201 and the choke 202 are formed, and support means 213 for maintaining a predetermined gap between the microstrip substrate 203 and the reflecting plate 201 are formed. That is, the ground plane 207 and the second stub 210 are formed on the front surface of the microstrip substrate 203, and the copier 204, the waveguide 205, the reflector 206, and the microstrip line ( 208 and a first stub 209 are formed, and a reflecting plate 201 and a choke 202 having bent surfaces are formed under the microstrip substrate 203. In addition, support means 213 is formed between the microstrip substrate 203 and the reflecting plate 201 to maintain a predetermined interval.

4 is a diagram illustrating a voltage standing wave ratio of a high gain microstrip antenna using a yagi antenna structure according to the present invention, and FIG. 5 is a diagram illustrating a radiation pattern of a high gain microstrip antenna using a yagi antenna structure according to the present invention. It shows the measured value in 1.75 ~ 1.87GHz band which is domestic personal mobile communication (PCS) frequency. As shown in FIG. 4, the voltage standing wave ratio (VSWR) may be determined to be 1.3 or less in the personal mobile communication frequency band. In addition, as shown in Figure 5 it can be seen that the antenna according to the present invention exhibits a high gain of 10dBi or more and front and rear ratio of 20dB or more.

FIG. 6 is a diagram illustrating a structure in which the element 205 of the high gain microstrip antenna using the Yagi antenna structure according to the present invention is increased. The present invention can improve the gain by increasing the waveguide 205. Such a design change increases the size of the microstrip substrate and the reflecting plate 201 and the waveguide 205 in the same manner as the above embodiment. It is possible only by further forming, and may be further provided with the said 2nd stub 208 as needed.

The present invention described above is not limited to the above-described embodiment and the accompanying drawings, and various substitutions and changes can be made without departing from the technical spirit of the present invention. It is obvious to those who have it.

High-gain microstrip antenna using Yagi antenna structure according to the present invention, in order to solve the above problems by forming a Yagi antenna pattern on the microstrip substrate and having a reflecting plate bent in the front of the lower side to suppress the side lobe It has an excellent ratio, high directivity and gain in one direction, and wideband electrical characteristics.

In addition, the present invention is easy to increase the gain through the increase of the device while using a small area by configuring the Yagi antenna pattern on the microstrip substrate, and can be miniaturized and lightweight, and the structure is simple, reducing the cost of mass production And has the effect of obtaining uniform properties.

Claims (10)

In a high gain antenna used in a wireless communication system, A copier having a half-wavelength dipole structure formed on a microstrip substrate to excite electromagnetic waves generated by magnetic current to parasitic elements; A microstrip line connected to the copier and having a feed point formed at one side to match a signal, and having an input impedance matched thereto; A first stub formed at a predetermined position on the microstrip line to match the input impedance of the microstrip line; A reflector formed at the rear of the copier, having a structure slightly longer than half wavelength to reflect back radiation of electromagnetic waves generated by the copier; A waveguide formed in front of the copier, the waveguide having a structure slightly shorter than half wavelength in order to improve gain through forward radiation of electromagnetic waves generated from the copier and electromagnetic waves reflected from the reflector; A ground plane formed opposite to the reflector on an opposite side of the microstrip substrate to radiate impedance matching and electromagnetic waves into free space; A second stub formed on an opposite side of the microstrip substrate to be adjacent to a ground plane to improve impedance matching and bandwidth; A reflection plate bent to have a high front and rear ratio by maintaining a height of a predetermined interval formed by an air layer under the microstrip substrate, reflecting electromagnetic waves radiated on the microstrip substrate, and suppressing side lobes; A choke formed on the reflector to suppress electric beam tilt; A power supply connector connected to the power supply point to supply external power; And Support means for maintaining a predetermined distance between the microstrip substrate and the reflecting plate; High gain microstrip antenna using Yagi antenna structure comprising a. The method of claim 1, wherein the microstrip substrate, A high gain microstrip antenna using a Yagi antenna structure, wherein a copier, a microstrip line, a first stub, a reflector, and a waveguide are formed on a front surface thereof. The method of claim 1, wherein the microstrip substrate, A high gain microstrip antenna using a Yagi antenna structure, characterized in that a ground plane and a second stub are formed on its rear surface. The method of claim 1, wherein the copier, A high-gain microstrip antenna using a Yagi antenna structure, wherein the half-wavelength dipole structure has a length of 0.45 λ . The method of claim 1, wherein the waveguide, A high gain microstrip antenna using a Yagi antenna structure, characterized in that it has a length of 0.3 λ shorter than half wavelength and at least one is provided in front of the copier. The method of claim 1, wherein the reflector, A high gain microstrip antenna using a Yagi antenna structure, which has a length of 0.53 λ longer than half wavelength and is provided at an interval of 0.18 λ at the rear of the copier. The method of claim 1, wherein the microstrip line, And a first stub for matching the input impedance to the predetermined position. The method of claim 1, wherein the ground plane, And a second stub formed adjacent to the reflector on an opposite side of the microstrip substrate, the second stub adjacent thereto. The method of claim 1, wherein the reflecting plate, Is formed on the bottom of the microstrip substrate, high-gain microstrip antenna using a Yagi antenna structure, characterized in that to reflect the electromagnetic radiation radiated from the microstrip substrate and suppress the side lobe. The method of claim 1, wherein the choke, The high gain microstrip antenna using the Yagi antenna structure, characterized in that formed on the reflector to suppress the electrical beam tilt.