KR20180059283A - Antenna Apparatus - Google Patents

Abstract

The present invention relates to an antenna device. The device according to an embodiment of the present invention includes a first antenna including a first radiation part formed on one side of a first substrate with a meander pattern and transmitting and receiving a radio wave by receiving a signal, and a first reflection part formed on one side of a second substrate separated from the first substrate at a predetermined distance, with the meander pattern and reflecting the radio wave. According to the present invention, an antenna element is formed on the substrate with the meander pattern, thereby achieving miniaturization and weight reduction, a high gain and high directivity.

Description

Antenna Apparatus

The present invention relates to an antenna device, and more particularly, to an antenna device capable of forming an antenna element in a meander pattern on a substrate.

Dipole antennas, pole antennas, loop antennas, parabola antennas, or yagi antennas are used as antenna devices for broadcasting or communication today.

One of the most widely used antennas for broadcasting or communication is the Yagi antenna developed by Professor Ueda who was first developed by Professor Yagi of Japan with his student and is widely used today as TV antenna. The Yagi antenna is widely used for transmission / reception of a microwave, TV reception, and the like, and the components of the antenna can be all arranged on one plane. The Yagi antenna can have a high gain and a high directivity by using a principle that a wave is induced in a reflector or a waveguide which is an adjacent element due to a magnetic field generated by a radiator supplied with a radio signal.

However, the conventional Yagi antenna has a problem in that it has a physical size because a separation distance exists between the Yagi antenna elements.

As a result, there is a problem that spatial and structural restrictions are generated in the installation of the Yagi antenna.

Korean Patent No. 10-0355090 (registered on September 19, 2002)

SUMMARY OF THE INVENTION Accordingly, it is an object of the present invention to provide an antenna device that can be miniaturized and lightweight, and can have high gain and high directivity by forming an antenna element in a meander pattern on a substrate.

Further, the present invention includes other objects that can be achieved from the construction of the present invention described later, in addition to the objects explicitly mentioned.

According to an aspect of the present invention, there is provided an antenna device including a first radiation part formed on a first surface of a first substrate and having a meander pattern and receiving a signal to transmit and receive a radio wave, And a first antenna including a first reflector formed in a meander pattern on one surface of the second substrate spaced apart by a predetermined distance and reflecting the radio wave.

A second radiation part formed in a meander pattern on the other surface of the first substrate and supplied with the signal to transmit and receive the radio waves; and a second reflection part formed in a meander pattern on the other surface of the second substrate, The antenna may further include a second antenna.

The meander pattern of the first radiating part may be arranged to be rotated at the same angle as the meander pattern of the first reflecting part so as to face the meander pattern of the first reflecting part.

The meander pattern of the second radiating part may be arranged so as to be rotated at the same angle as the meander pattern of the second reflecting part so as to face the meander pattern of the second reflecting part.

Wherein the meander pattern of the second radiating part and the meander pattern of the second reflecting part are arranged so as to be rotated by a predetermined rotational angle at an angle at which the meander pattern of the first radiating part and the meander pattern of the first reflecting part are arranged .

The meander pattern of the first radiating part may be curved outward from the center of the first substrate and the meander pattern of the first reflecting part may be curved outward from the center of the second substrate.

Wherein the meander pattern of the first radiating part is longer in the circumferential direction from the center of the first substrate toward the outward direction and the meander pattern of the first reflector is longer in the circumferential direction .

The meander pattern of the first radiating part may be arranged symmetrically with respect to the center of the first substrate, and the meander pattern of the first reflecting part may be arranged symmetrically with respect to the center of the second substrate.

The first antenna may further include a first waveguide part formed in a meander pattern on one surface of a third substrate spaced apart from the first substrate in a direction opposite to the second substrate to guide the wave .

The second antenna may further include a second waveguide formed in a meander pattern on the other surface of the third substrate spaced apart from the first substrate in a direction opposite to the second substrate to guide the wave .

The total length of the meander pattern of the first radiating part may be shorter than the total length of the meander pattern of the first reflecting part and longer than the total length of the meander pattern of the first waveguide part.

The total length of the meander pattern of the second radiating part may be shorter than the total length of the meander pattern of the second reflecting part and longer than the total length of the meander pattern of the second waveguide part.

And a first impedance matching unit and a second impedance matching unit disposed for impedance matching between the first antenna and the second antenna, respectively.

A power distributor for distributing the power of the generated signal to the power feeder for generating the signal, and a power distributor for delaying the phase of the distributed signal and supplying the phase delayed signal to the first radiator and the second radiator respectively The first phase delay unit and the second phase delay unit.

The first phase delay unit and the second phase delay unit may delay the phases of the distributed signals at different angles.

And a switching unit switching the first radiation unit and the second radiation unit to selectively receive the generated signal.

As described above, according to the antenna device of the embodiment of the present invention, since the antenna device is formed in the meander pattern on the substrate, the antenna device can be miniaturized and lightweight, and has high gain and high directivity.

In addition, it has the effect of eliminating the space limitation in the installation of the antenna device, reducing the cost due to the mass production and obtaining uniform characteristics.

In addition, when the Yagi antenna is vertically arranged to realize the multi-polarization according to the wireless system environment, a dual polarization (vertical, horizontal) Yagi antenna can be realized, and when the power feeding circuit having a phase delay is installed, the circular polarized Yagi antenna can be easily There is one advantage.

Accordingly, it can be installed in a sensor of the Internet (IoT), a mobile device, or a portable device, and can be utilized in a wide range of fields such as logistics management for smart recognition and smart factory.

On the other hand, the effects of the present invention are not limited to those described above, and other effects that can be derived from the constitution of the present invention described below are also included in the effects of the present invention.

1 is a schematic view of an antenna apparatus according to a first embodiment of the present invention.
2 is a schematic view illustrating an antenna device according to a second embodiment of the present invention.
3 is a schematic view of an antenna device according to a third embodiment of the present invention.
4 is a configuration diagram of an antenna apparatus according to a fourth embodiment of the present invention.
5 is a configuration diagram of an antenna device according to a fifth embodiment of the present invention.
6 is a configuration diagram of an antenna apparatus according to a sixth embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention.

FIG. 1 shows a schematic view of an antenna device according to a first embodiment of the present invention.

As shown in Fig. 1, the antenna apparatus 1 includes a first antenna 100. The first antenna 100 includes a plurality of antennas.

The first antenna 100 includes a first radiation part 120 formed in a meander pattern on one surface of the first substrate 30 and fed with a signal to transmit and receive a radio wave, And a first reflector 140 that reflects a radio wave.

The first substrate 30 and the second substrate 50 may be formed of FR4 or the like and the first substrate 30 may be spaced apart from the second substrate 50 at predetermined intervals.

The first radiation part 120 may be a meander-shaped conductor pattern, and may be disposed on the upper surface of the first substrate 30, for example. The first radiation unit 120 may receive a radio wave having a predetermined frequency and radiate a radio wave having a predetermined frequency when a signal is supplied.

The first reflector 140 may be a meander-shaped conductor pattern, and may reflect a radio wave radiated from the first radiator 120. The total length of the meander pattern of the first radiation portion 120 may affect the operating frequency.

If the total length of the meander pattern of the first reflector 140 is longer than the total length of the meander pattern of the first radiator 120, the antenna can be operated as a high directivity yagi antenna. When the distance between the first radiation unit 120 and the first reflection unit 140 approaches the resonance frequency f0 due to the length of the first radiation unit 120 and the resonance frequency f0 due to the mutual inductance value, Resonance (f1) due to the length of the multi-band antenna is generated. Therefore, it is possible to operate as a multi-band antenna having wideband and multi-band characteristics due to multi-resonance.

The distance between the first radiation unit 120 and the first reflection unit 140 may vary depending on the length of the first radiation unit 120 and the first reflection unit 140, The configuration of operating as a band antenna can be similarly applied to the antenna devices of Figs. 2 to 6 described below.

The meander pattern of the first radiation unit 120 may be arranged to be rotated at the same angle as the meander pattern of the first reflector 140 so as to face the meander pattern of the first reflector 140. For example, when the meander pattern of the first radiation unit 120 is arranged on the first substrate 30 in a state rotated by 90 degrees about the predetermined axis S1, The pattern may be arranged on the second substrate 50 in a state rotated by 90 degrees around the predetermined axis S2.

The meander pattern of the first radiation unit 120 is formed to bend outwardly from the center P1 of the first substrate 30 and the meander pattern of the first reflection unit 140 is formed on the second substrate 50, As shown in FIG. For example, the meander pattern of the first radiation part 120 may be repeatedly bent in the outward direction from the center P1 of the first substrate 30, The pattern may be repeatedly bent from the center P2 of the second substrate 50 toward the outward direction.

And the meander pattern of the first radiation part 120 becomes longer in the circumferential direction d1 from the center P1 of the first substrate 30 to the outward direction and the meander pattern of the first reflector 140 The length d2 in the circumferential direction may become longer toward the outward direction from the center P2 of the second substrate 50. [ That is, the meander pattern of the first radiation unit 120 and the meander pattern of the first reflection unit 140 may have a fan shape. A plurality of pitches w1 may be the same in the meander pattern of the first radiation unit 120 and a plurality of pitches w2 may be the same in the meander pattern of the first reflector 140 . However, the pitch can be configured to be adjustable depending on the operating condition or the state of the antenna device 1, or the like.

The meander pattern of the first radiation unit 120 is arranged symmetrically with respect to the center P1 of the first substrate 30 and the meander pattern of the first reflector 140 is disposed on the second substrate 50, And may be arranged symmetrically with respect to the center P2 of the first and second light sources. For example, the meander pattern of the first radiation unit 120 may be arranged to be rotated by 90 degrees and 270 degrees about the predetermined axis S1, respectively.

As described above, in the case of the first antenna made up of two antenna elements, the directivity is exhibited by the first reflector 140, so that the waveguide is removed, and only the first reflector 120 and the first reflector 140 are used, By forming a pattern and disposing it on a substrate, the antenna device can be realized in a planar shape deviating from the three-dimensional structure possessed by the conventional antenna, and the physical size can be reduced while maintaining the electrical length of the first antenna.

2 shows a schematic view of an antenna device according to a second embodiment of the present invention.

Referring to FIG. 2, the antenna device 1 includes a first antenna 100 and a second antenna 200. 1 are denoted by the same reference numerals as those in FIG. 1, and detailed description of the same elements as those described previously will be omitted.

The first antenna 100 is formed in a meander pattern on one surface of the first substrate 30 and is connected to the first radiation unit 120 through which a signal is supplied to transmit and receive a radio wave and the first substrate 30, And a first reflector 140 formed in a meander pattern on one surface of the second substrate 50 to reflect the radio waves.

The second antenna 200 includes a second radiation part 220 formed in a meander pattern on the other surface of the first substrate 30 and receiving a signal to transmit and receive a radio wave and a second radiation part 220 on a second surface of the second substrate 50, And a second reflector 240 that reflects the radio wave.

The second radiation part 220 may be a meander-shaped conductor pattern, and may be disposed on the lower surface of the first substrate 30, for example. When the signal is supplied, the second radiation unit 220 can receive radio waves having a predetermined frequency and radiate radio waves having a predetermined frequency.

The second reflector 240 may be a meander-shaped conductor pattern, and may reflect a radio wave radiated from the second radiator 220. The total length of the meander pattern of the second radiation portion 220 may affect the operating frequency and the total length of the meander pattern of the second reflection portion 240 may be greater than the total length of the meander pattern of the second radiation portion 220. [ So that it can serve as a reflector of the Yagi antenna.

The meander pattern of the second radiation unit 220 may be arranged to be rotated at the same angle as the meander pattern of the second reflection unit 240 so as to face the meander pattern of the second reflection unit 140. For example, if the meander pattern of the second radiation unit 220 is disposed in a state of being rotated by 360 ° (0 °) about the predetermined axis S1 at the lower surface of the first substrate 30, The meander pattern of the first substrate 240 may be arranged to be rotated by 360 ° (0 °) about the predetermined axis S2 on the lower surface of the second substrate 50.

The meander pattern of the second radiation part 220 and the meander pattern of the second reflection part 240 are arranged such that the meander pattern of the first radiation part 120 and the meander pattern of the first reflection part 140 are arranged And may be arranged to be rotated by a predetermined angle of rotation from an angle. That is, the angle at which the meander pattern of the second radiation unit 220 is rotated about the predetermined axis S1 is the angle at which the meander pattern of the first radiation unit 120 is rotated about the predetermined axis S1 And the angle of rotation of the meander pattern of the second reflector 240 about the predetermined axis S2 is set such that the meander pattern of the first reflector 140 overlaps the predetermined axis S2, As shown in FIG. For example, the meander pattern of the second radiation part 220 and the meander pattern of the second reflection part 240 may be formed so that the meander pattern of the first radiation part 120 and the meander pattern of the first reflection part 140 And may be arranged rotated by 90 degrees from the arranged angle.

As described above, the meander pattern of the second radiation unit 220 can be disposed so as not to overlap with the meander pattern of the first radiation unit 120, Can be arranged so as not to overlap with the meander pattern of the second electrode (140).

The meander pattern of the second radiation part 220 is formed to bend outward from the center P1 of the first substrate 30 and the meander pattern of the second reflection part 240 is formed on the second substrate 50, As shown in FIG. For example, the meander pattern of the second radiation part 220 may be repeatedly bent toward the outward direction from the center P1 of the first substrate 30, and the meander pattern of the second reflector 240 may be repeated. The pattern may be repeatedly bent from the center P2 of the second substrate 50 toward the outward direction.

And the meander pattern of the second radiation unit 220 becomes longer in the circumferential direction d3 from the center P1 of the first substrate 30 toward the outward direction, The length d4 in the circumferential direction may become longer toward the outer side from the center P2 of the second substrate 50. [ That is, the meander pattern of the second radiation unit 220 and the meander pattern of the second reflection unit 240 may have a fan shape. A plurality of pitches w3 may be the same in the meander pattern of the second radiation unit 220 and a plurality of pitches w4 may be the same in the meander pattern of the second reflector 240 , The pitch can be varied according to the operating condition or the state of the antenna apparatus 1 or the like.

The meander pattern of the second radiation unit 220 is disposed symmetrically with respect to the center P1 of the first substrate 30 and the meander pattern of the second reflection unit 240 is disposed on the second substrate 50, And may be arranged symmetrically with respect to the center P2 of the first and second light sources. For example, the meander pattern of the second radiation unit 220 may be arranged to be rotated by 360 ° and rotated 180 ° about the predetermined axis S1, respectively.

3 shows a schematic view of an antenna device according to a third embodiment of the present invention.

Referring to FIG. 3, the antenna device 1 includes a first antenna 100 and a second antenna 200. 1 and 2 are denoted by the same reference numerals as those in FIG. 1 and FIG. 2, and detailed description of the same contents as those described above will be omitted.

The first antenna 100 may include a first radiation unit 120, a first reflector 140, and a first waveguide unit 160.

The first waveguide section 160 is formed in a meander pattern on one side of the third substrate 70 spaced apart from the first substrate 30 in a direction opposite to the second substrate 50 to induce propagation . The first waveguide section 160 may be a meander-shaped conductor pattern. When the first waveguide section 140 is disposed on one side of the first radiation section 120, So that the radio wave can be induced. That is, the first waveguide unit 160 may be disposed on one surface of the third substrate 70, which is opposite to the first reflector 140, with the first radiation unit 120 as a center, As shown in FIG. The total length of the meander pattern of the first waveguide section 160 may be greater than the total length of the first radiation section 120 of the first waveguide section 120. The first waveguide section 160 may further radiate radio waves radiated from the first radiation section 120, And may be formed to be shorter than the total length of the meander pattern to serve as a waveguide of the Yagi antenna.

The meander pattern of the first waveguide section 160 may be arranged to be rotated at the same angle as the meander pattern of the first radiation section 120 so as to face the meander pattern of the first radiation section 120. For example, if the meander pattern of the first radiation unit 120 is disposed on the first substrate 30 in a state rotated by 90 degrees about the predetermined axis S1, The pattern may be disposed on the third substrate 70 in a state rotated by 90 degrees around a predetermined axis S3.

The meander pattern of the first waveguide section 160 may be formed to bend outward from the center P3 of the third substrate 70. For example, the meander pattern of the first waveguide section 160 may be repeatedly bent in the outward direction from the center P3 of the third substrate 70. [

The meander pattern of the first waveguide unit 160 may have a sector shape having a longer circumferential length d5 from the center P3 of the third substrate 70 toward the outer side. A plurality of pitches w5 in the meander pattern of the first waveguide unit 160 may be the same, but the pitch may vary depending on the operating condition or the state of the antenna apparatus 1. [

In addition, the meander pattern of the first waveguide section 160 is symmetrically arranged with respect to the center P3 of the third substrate 70. For example, the meander pattern of the first waveguide section 160 may be a predetermined axis Can be arranged in a state of being rotated by 90 ° and by 270 °, respectively, with respect to the center line S3.

The second antenna 200 may include a second radiation unit 220, a second reflection unit 240, and a second waveguide unit 260.

The second waveguide section 260 is formed in a meander pattern on the other surface of the third substrate 70 spaced apart from the first substrate 30 in the direction opposite to the second substrate 50, . When the second reflecting portion 240 is disposed on one side of the second radiating portion 220, the second radiating portion 260 may be formed on the other side of the second radiating portion 220 So that the radio wave can be induced. That is, the second waveguide part 260 may be disposed on the other surface of the third substrate 70 opposite to the second reflecting part 240 about the second radiation part 220, As shown in FIG. The total length of the meander pattern of the second waveguide part 260 is greater than the total length of the second radiation part 220 of the second waveguide part 220. The second waveguide part 260 may further radiate the radio wave radiated from the second radiation part 220, And may be formed to be shorter than the total length of the meander pattern to serve as a waveguide of the Yagi antenna.

The meander pattern of the second waveguide section 260 may be arranged to be rotated at the same angle as the meander pattern of the second radiation section 220 so as to face the meander pattern of the second radiation section 220. For example, if the meander pattern of the second radiation unit 220 is disposed on the first substrate 30 in a state rotated by 360 ° (0 °) around the predetermined axis S1, the second waveguide unit 260 ) May be arranged on the third substrate 70 in a state rotated by 360 ° (0 °) about a predetermined axis S3.

The meander pattern of the second waveguide section 260 may be arranged so as to be rotated by a predetermined rotation angle at an angle at which the meander pattern of the first waveguide section 160 is disposed. That is, the angle at which the meander pattern of the second waveguide section 260 is rotated about the predetermined axis S3 is the angle at which the meander pattern of the first waveguide section 160 is rotated about the predetermined axis S1 . ≪ / RTI > For example, the meander pattern of the second waveguide section 260 may be arranged to be rotated by 90 degrees from the angle at which the meander pattern of the first waveguide section 160 is arranged.

The meander pattern of the second waveguide section 260 may be formed to bend outward from the center P3 of the third substrate 70. For example, the meander pattern of the second waveguide section 260 may be repeatedly bent in the outward direction from the center P3 of the third substrate 70. [

The meander pattern of the second waveguide unit 260 may be formed into a fan shape having a longer circumferential length d6 from the center P3 of the third substrate 70 toward the outer side. A plurality of pitches w6 may be the same in the meander pattern of the second waveguide section 260. However, the pitch may vary depending on the operating condition or the state of the antenna device 1 or the like.

In addition, the meander pattern of the second waveguide section 260 is arranged symmetrically with respect to the center P3 of the third substrate 70. For example, the meander pattern of the second waveguide section 260 may be formed on a predetermined axis (0 °) and 180 ° around the center line S3 as shown in FIG.

As described above, if a waveguide is added to two antenna elements, it can be utilized as an antenna apparatus with improved performance. If the total length of the meander pattern of the waveguide portion is shorter than the total length of the meander pattern of the radiating portion, the waveguide serves as a waveguide, so that higher directivity can be obtained.

4 shows a configuration diagram of an antenna device according to a fourth embodiment of the present invention.

4, the antenna device 1 includes a first antenna 100, a second antenna 200, a feeder 310, a first impedance matching unit 320, and a second impedance matching unit 340 . 1 to 3 are denoted by the same reference numerals as those in Figs. 1 to 3, and detailed description of the same elements as those described above will be omitted.

The first impedance matching unit 320 may be disposed for impedance matching of the first antenna 100 and the second impedance matching unit 340 may be disposed for impedance matching of the second antenna 200. [

The first impedance matching unit 320 may perform impedance matching such that the impedances of the feeder 310 and the first antenna 100 that generate signals are equal to each other. To this end, the first impedance matching unit 320 may include a balun circuit.

The second impedance matching unit 340 may perform impedance matching such that impedances of the feeder 310 and the second antenna 200 are equal to each other. For this purpose, the second impedance matching unit 340 may include a balun circuit.

As described above, since the antenna device 1 is formed in a dipole shape, a balun circuit can be applied, and a linear polarization can be generated because the radiation portion, the reflection portion, and the waveguide portion are disposed on the same plane.

5 shows a configuration diagram of an antenna device according to a fifth embodiment of the present invention.

5, the antenna device 1 includes a first antenna 100, a second antenna 200, a power feeder 420, a power divider 440, a first phase delay unit 460, And may include a phase delay unit 480. 1 to 3 are denoted by the same reference numerals as those in Figs. 1 to 3, and detailed description of the same elements as those described above will be omitted.

The power feeder 420 may generate and provide a signal to the power distributor 440.

The power divider 440 can distribute the power of the generated signal. At this time, the power divider 440 can distribute the power of the generated signal to the first antenna 100 and the second antenna 200. At this time, the power divider 440 can distribute the power of the signal equally to the first antenna 100 and the second antenna 200, and can appropriately distribute the power of the signal according to the operating conditions, To the first antenna (100) and the second antenna (200).

The first phase delay unit 460 may delay the phase of the distributed signal by a predetermined angle and supply the phase delayed signal to the first radiation unit 120.

The second phase delay unit 480 may delay the phase of the distributed signal by a predetermined angle, and may supply the phase delayed signal to the second radiation unit 220.

Here, the first phase delay unit 460 and the second phase delay unit 480 may delay the phases of the distributed signals at different angles. For example, the first phase delay unit 460 may delay the phase of the distributed signal by 0 °, and the second phase delay unit 480 may delay the phase of the distributed signal by 90 °.

The first antenna 100 and the second antenna 200 are disposed and the first and second antennas 100 and 200 are provided with the first phase delay unit 460 and the second phase delay unit 460. [ When the signal having a phase difference of 90 degrees is supplied to the first antenna 100 and the second antenna 200 after the antenna 480 is connected to the first antenna 100 and the second antenna 200, Circular Polarization is a polarized wave that rotates periodically in a section perpendicular to the direction of propagation of radio waves (polarity direction of the electric field with respect to propagation direction) When the polarized waves are combined, the resulting composite electric field vector is a circular polarized wave because it draws a circular shape.

According to an embodiment of the present invention, a first impedance matching unit is further disposed between the first phase delay unit 460 and the first radiation unit 120, and the second phase delay unit 480 and the second radiation unit 220 may further include a second impedance matching unit to perform impedance matching.

6 shows a configuration diagram of an antenna device according to a sixth embodiment of the present invention.

Referring to FIG. 6, the antenna device 1 may include a first antenna 100, a second antenna 200, a feeder 520, and a switching unit 540. 1 to 3 are denoted by the same reference numerals as those in Figs. 1 to 3, and detailed description of the same elements as those described above will be omitted.

The power feeder 520 may generate a signal and provide the signal to the switching unit 540.

The switching unit 540 may switch the signal generated by the power feed unit 520 to selectively receive the first radiation unit 120 and the second radiation unit 220. The switching unit 540 is provided between the power feeding unit 520 and the first and second radiation units 120 and 220 so that signals are simultaneously applied to the first radiation unit 120 and the second radiation unit 220. [ All of the plurality of switching elements (not shown) arranged respectively can be turned on. The switching unit 540 may turn on the switching devices (not shown) corresponding to the corresponding radiation units so that signals are sequentially applied to the first radiation unit 120 and the second radiation unit 220. At this time, the switching unit 540 may operate under the control of a control unit (not shown).

After the first antenna 100 and the second antenna 200 are disposed and the switching unit 540 is connected to the first antenna 100 and the second antenna 200, It is possible to generate horizontal polarized waves and vertical polarized waves that are polarization-isolated from each other according to the switching operation, thereby generating dual polarized waves.

Meanwhile, a plurality of antenna apparatuses according to an embodiment of the present invention may be arranged and used as an array antenna.

For example, when an array antenna having a plurality of antenna apparatuses including a first antenna and a second antenna is implemented, a signal generated from the power feeding unit is distributed through a power distributing unit to divide the power of the distributed signal into an in- It is possible to generate extended polarized waves by providing different polarization characteristics by providing a plurality of antenna units, respectively. Further, there is an advantage that a vertical polarized wave and a horizontal polarized wave can be separately used by adding a switching unit according to the situation.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, Of the right.

1: Antenna device
100: first antenna 120: first radiation part
140: first reflecting portion 160: first waveguide portion
200: second antenna 220: second radiation part
240: second reflecting part 260: second waveguide part
310, 420, 520:
320: First Impedance Matching Unit 340: Second Impedance Matching Unit
440: power divider 460: first phase delay unit
480: second phase delay unit 540: switching unit

Claims (16)

A first radiation part formed in a meander pattern on one surface of the first substrate and supplied with a signal to transmit and receive radio waves and a second radiation part formed in a meander pattern on one surface of the second substrate spaced apart from the first substrate by a predetermined gap, A first antenna including a first reflector for reflecting radio waves
. The method of claim 1,
A second radiation part formed in a meander pattern on the other surface of the first substrate and supplied with the signal to transmit and receive the radio waves; and a second reflection part formed in a meander pattern on the other surface of the second substrate, And a second antenna including a second antenna. 3. The method of claim 2,
The meander pattern of the first radiation part
And is arranged so as to be rotated at the same angle as the meander pattern of the first reflector so as to face the meander pattern of the first reflector. 4. The method of claim 3,
Wherein the meander pattern of the second radiating portion
And is arranged so as to be rotated at the same angle as the meander pattern of the second reflector so as to face the meander pattern of the second reflector. 5. The method of claim 4,
Wherein the meander pattern of the second radiating part and the meander pattern of the second reflecting part
Wherein the meander pattern of the first radiating part and the meander pattern of the first reflecting part are arranged so as to be rotated by a predetermined rotation angle. The method of claim 1,
The meander pattern of the first radiation part
Wherein the first substrate is formed so as to bend outward from a center of the first substrate,
Wherein the meander pattern of the first reflector
Wherein the second substrate is bent in an outward direction from a center of the second substrate. The method of claim 6,
The meander pattern of the first radiation part
The length in the circumferential direction becomes longer toward the outer side from the center of the first substrate,
Wherein the meander pattern of the first reflector
And the length in the circumferential direction becomes longer toward the outer side from the center of the second substrate. 8. The method of claim 7,
The meander pattern of the first radiation part
A second substrate disposed symmetrically with respect to a center of the first substrate,
Wherein the meander pattern of the first reflector
Wherein the second substrate is symmetrically disposed with respect to a center of the second substrate. 3. The method of claim 2,
The first antenna includes:
And a first waveguide part formed in a meander pattern on one surface of a third substrate spaced apart in a direction opposite to the second substrate with respect to the first substrate to guide the wave. The method of claim 9,
The second antenna includes:
And a second waveguide portion formed in a meander pattern on the other surface of the third substrate spaced apart from the first substrate in a direction opposite to the second substrate. 11. The method of claim 10,
Wherein the total length of the meander pattern of the first radiating part
And the second reflector is shorter than the total length of the meander pattern of the first reflector,
And the total length of the meander pattern of the first waveguide portion is longer than the total length of the meander pattern of the first waveguide portion. 12. The method of claim 11,
Wherein the total length of the meander pattern of the second radiating part
Is shorter than the total length of the meander pattern of the second reflecting portion,
And the total length of the meander pattern of the second waveguide portion is longer than the total length of the meander pattern of the second waveguide portion. 3. The method of claim 2,
And a first impedance matching unit and a second impedance matching unit arranged for impedance matching of the first antenna and the second antenna, respectively. 3. The method of claim 2,
A feeding part for generating the signal,
A power distributor for distributing the power of the generated signal, and
Further comprising a first phase delay unit and a second phase delay unit for delaying the phase of the distributed signal and supplying the delayed signal to the first radiation unit and the second radiation unit, respectively. The method of claim 14,
Wherein the first phase delay unit and the second phase delay unit comprise:
And delaying the phase of the distributed signal by different angles. 3. The method of claim 2,
A feeding part for generating the signal, and
And the switching unit switches the first and second radiation units to selectively receive the generated signals.

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