KR20100004650A - Triple-band antenna with spiral ring shaped parasitic patches - Google Patents

Abstract

PURPOSE: A triple-band antenna with spiral ring shaped parasitic patches is provided to be operated without interference by using two radiators having parasitic patches. CONSTITUTION: A tri-bandwidth antenna comprises a first radiator and a second radiator antennas(110,120) and a feeding unit(130). The first and the second radiator antenna includes an FR4 substrate and an eddy type parasitic patch. The FR4 substrate has a rod shape. The eddy type parasitic patch is attached on the single-side of the FR4 substrate. A feeding unit comprises a matching stub and a lumped element(132). A matching stub and the lumped element are located on the surface of a feeding line. A feeding unit is connected to a feeding point(131) of a first and second radiator antenna.

Description

Triple-Band Antennas with Memphis-type Parasitic Patches {TRIPLE-BAND ANTENNA WITH SPIRAL RING SHAPED PARASITIC PATCHES}

The present invention relates to a triple-band antenna having a memetic parasitic patch, and in particular, by applying two radiators and attaching a memetic parasitic patch and modifying the feeder circuit design, T-DMB (Band-III) / DVB-H / T-DMB (L-Band) relates to an antenna capable of operating in the triple band.

Recently, with the rapid development of TV broadcasting technology, there is a demand for a multiband antenna capable of efficiently receiving a high quality broadcasting service. Miniature antennas capable of portable broadcasting services have antennas that can operate in a specific band and operate in a certain area.

That is, in the past, the T-DMB band and the DVB-H band have been implemented as a single band or a dual band, but recently T-DMB (Band-III) / There is an urgent need for an antenna capable of operating in the DVB-H / T-DMB (L-Band) triple band.

The present invention implements a triple band antenna using two radiators having a memetic parasitic patch, thereby providing an antenna that operates without interference in the triple band.

The present invention provides a triple band antenna that can receive a T-DMB (L-Band) at various locations around the world by implementing a triple band antenna using two radiators having a memetic parasitic patch.

According to an embodiment of the present invention, a three-band antenna having a memetic parasitic patch includes a first radiator antenna and a first radiator antenna having a symmetrical parasitic patch attached to an upper end of a rod-shaped FR4 substrate. It is provided spaced apart, and includes a second radiator antenna attached to the top of one side of the rod-shaped FR4 substrate symmetric parasitic patch

According to an aspect of the present invention, the apparatus may further include a system ground including a feeding part, and the feeding part may include a matching stub for impedance matching and a lumped element positioned on a feeding line. have.

According to one aspect of the invention, the first radiator antenna, a rod-shaped FR4 substrate, a main radiator attached to one side of the FR4 substrate, the lower end of the serpentine form, one attached to the lower end of the main radiator The above-described lumped inductor, a symmetrical parasitic patch attached to the upper end of the main radiator, and a U-shaped parasitic patch attached to the lower end of the other side of the FR4 substrate may be included.

According to one aspect of the present invention, a rod-shaped FR4 substrate, a main radiator attached to both sides of the FR4 substrate and the upper end of the serpentine form, a parasitic patch attached to both sides of the lower side of the FR4 substrate and one of the FR4 substrate It may include one or more memetic parasitic patches attached to the top side.

In one embodiment of the present invention, by implementing a three-band antenna using two radiators provided with a symmetric parasitic patch, an antenna that operates without interference in the triple band is provided.

In one embodiment of the present invention, by implementing a three-band antenna using two radiators with a symmetric parasitic patch, a three-band antenna capable of receiving T-DMB (L-Band) at various locations around the world Is provided.

Hereinafter, with reference to the contents described in the accompanying drawings will be described in detail an embodiment according to the present invention. However, the present invention is not limited or limited by the embodiments. Like reference numerals in the drawings denote like elements.

FIG. 1 is an enlarged view of an antenna and a ground part of an antenna having a memetic parasitic patch according to an exemplary embodiment of the present invention.

Referring to FIG. 1, the antenna 100 having a memetic parasitic patch includes a first radiator antenna 110 and a second radiator antenna 120. In this case, the antenna 100 having a memetic parasitic patch may include a system ground including a power feeding unit 130.

The first radiator antenna 110 may include a symmetrical parasitic patch on one side of the rod-shaped FR4 substrate, and may be mounted on the system ground of the FR4 substrate.

The second radiator antenna 120 is disposed in parallel with the first radiator antenna 110, and is installed at a predetermined interval. Here, the interval spaced apart from the first radiator antenna 110 may be installed with a predetermined interval so that the total width (W) including the width of the first radiator antenna 110 and the second radiator antenna 120 is 5mm. . In this case, like the first radiator antenna 110, the second radiator antenna 120 also attaches a membranous parasitic patch to the upper end of one side of the rod-shaped FR4 substrate.

In this case, by using a memetic parasitic patch, impedance bandwidths of T-DMB (Band-III), DVB-H, and T-DMB (L-Band) can be satisfied.

The feed unit 130 may include a matching stub 130 and a lumped element 132. That is, the power supply unit 130 may include a matching stub and a concentrator so that the power supply unit 130 is connected to the feeding point 131 of the first radiator antenna and the second radiator antenna to be fed. As such, the matching element 132 and the matching stub 130 may be disposed on the feed line to reduce the matching loss. The concentrator 132 may be a coil inductor.

2 is an enlarged view of a first radiator antenna according to an embodiment of the present invention.

Referring to FIG. 2, the first radiator antenna 200 includes a main radiating element 230, a spiral ring shaped parasitic patches 210, and a rod-shaped FR4 substrate 220. A lumped element 240, a parasitic patch 250, and a via hole 260 may be included.

In addition, the rod-shaped FR4 substrate 220 may be a FR4 substrate having a thickness (X ₁ ) 0.8 mm, a horizontal length (Y ₁ ) 5 mm, a vertical length (Z ₁ ) 130 mm, and a relative dielectric constant of 4.4. Here, the main radiator 230 may be attached to one side of the rod-shaped FR4 substrate 220, and the lower end portion of the main radiator 230 may be formed in a serpentine shape. That is, as shown in FIG. 1, the lower end portion of the main copy body 230 may be configured in a shape in which the Hangul consonant dish pattern is symmetrically repeated. The vertical length A ₁ of the Hangul consonant Dison shape may be 10 mm.

In addition, the upper end portion of the main radiation unit 230 may be attached to the membranous parasitic patch 210. In this case, the memetic parasitic patch 210 may be attached in the form of two cells, and may be connected to the main radiator 230 through three via holes 260. In this case, the memdom-type parasitic patch 210 including two cells may set the vertical length S ₁ to 20 mm.

In addition, the concentration element 240 is disposed in the middle of the tortuous shape of the lower end of the main radiator 230, and the parasitic patch 250 is provided on the other side of the rod-shaped FR4 substrate 220 to adjust the bandwidth of the antenna. Can be.

In this way, an antenna that satisfies the T-DMB (Band-III) band is provided by arranging a meandering structure, a parasitic patch, a concentrated inductor, and a matching stub present in the feeding part of the system ground for the first radiator. can do.

3 is an enlarged view of a second radiator antenna according to an embodiment of the present invention.

Referring to FIG. 3, the second radiator antenna 300 includes a main radiating element 330, a spiral ring shaped parasitic patches 310, and a rod-shaped FR4 substrate 320. Parasitic patches 340 and via holes 350 may be included.

The rod-shaped FR4 substrate 320 may be an FR4 substrate having a thickness (X ₂ ) 0.8 mm, a width (Y ₂ ) 5 mm, a length (Z ₂ ) 80 mm, and a relative dielectric constant of 4.4. Here, the main radiator 330 may be attached to both sides of the rod-shaped FR4 substrate 320, and the upper end portion of the main radiator 330 may be configured to be serpentine. That is, as in the case of the first radiator antenna 200, the Hangul consonant dish shape may be configured to be symmetrically repeated. The vertical length A _{2 of} one Hangul consonant Dison shape may be 5 mm.

In addition, the upper end portion of the main radiator 330 on one side may be attached to the symmetrical parasitic patch 310. In this case, the memetic parasitic patch 310 may be attached in the form of six cells, and may be connected to the main radiator on the side where the memetic parasitic patch 310 is attached through the eleven via holes 350. Here, the memetic parasitic patch 310 including two cells may have a length S ₂ of 60 mm.

In addition, one or more parasitic patches 250 may be installed on both sides of the rod-shaped FR4 substrate 320 to adjust the bandwidth of the T-DMB band. At this time, the size (P) of the parasitic patch may be set to 25mm.

Thus, by arranging a meandering structure, a parasitic patch, etc. for a 2nd radiator, the antenna which satisfy | fills DVB-H and T-DMB (L-Band) band can be provided.

Accordingly, the first radiator antenna and the second radiator antenna are installed in parallel at a predetermined interval, and satisfy the T-DMB (Band-III) band through the first radiator antenna, and through the second radiator antenna, the DVB-H and By satisfying the T-DMB (L-Band) band, it is possible to provide an antenna satisfying the triple band.

4 is a view for explaining the return loss of the antenna provided with a symmetric parasitic patch in an embodiment of the present invention.

Referring to FIG. 4, there is shown a diagram 400 comparing the return loss with and without a medley-type parasitic patch.

That is, a graph 410 simulating the reflection loss in the absence of a memetic parasitic patch, a graph 420 in which the reflection loss is actually measured in the absence of a memetic parasitic patch, and a memetic parasitic patch. Each of the graphs 430 that actually measures the reflection loss in the case of having the?

When using SRS parasitic patches, the return loss is 6 dB in the T-DMB (Band-III) band (174 MHz to 216 MHz), and the DVB-H band (470 MHz to 870 MHz) and In the T-DMB (L-Band) band (1.45 GHz to 1.48 GHz), the return loss is 10dB. The calculation of the reflection coefficient shows that the standing wave ratio (VSWR) is smaller than 4 in the T-DMB (Band-Ⅲ) band and the standing wave ratio (VSWR) is smaller than 2 in the DVB-H / T-DMB (L-Band) band. Can be.

Therefore, by using the memetic parasitic patch, the operating bandwidth in the T-DMB band is increased, and the impedance matching performance in the T-DMB (L-Band) band is increased.

FIG. 5 is a diagram for describing a radiation pattern of an antenna provided with a symmetrical parasitic patch according to one embodiment of the present invention.

Referring to FIG. 5, antenna radiation patterns in the T-DMB (Band-III) band 510, the DVB-H band 520, and the T-DMB (L-Band) band 530 are illustrated. As shown in FIG. 5, the radiation pattern is isotropic in all frequency bands. That is, an antenna operating efficiently in the proposed triple band can be provided through the triple band antenna to which the symmetric parasitic patch of the present invention is attached.

FIG. 6 is a diagram for explaining gain characteristics of an antenna provided with a memetic parasitic patch according to an embodiment of the present invention.

Referring to FIG. 6, gain characteristics 610 of the T-DMB (Band-III) band (174 MHz to 216 MHz), gain characteristics 620 of the DVB-H band (470 MHz to 870 MHz), and T-DMB The gain characteristic 630 in the (L-Band) band (1.45 GHz to 1.48 GHz) is shown.

Here, the gain characteristics in the T-DMB (Band-III) band (174 MHz to 216 MHz) vary from -6.9 to 1.04 dBi, and the gain characteristics in the DVB-H band (470 MHz to 870 MHz) range from 0.18 to 4.99. The gain characteristics in the T-DMB (L-Band) band (1.45 GHz to 1.48 GHz) vary from 0.04 to 0.33 dBi.

That is, gain characteristics of -7 dBi or more in the T-DMB (Band-III) band, gain characteristics of -4 to 0 dBi or more in the DVB-H band, and 0 dBi or more in the T-DMB (L-Band) band In the proposed triple band, a gain characteristic of a certain level or more can be secured to provide an antenna capable of smooth reception in the triple band.

As described above, by applying two radiators which are dual patches, attaching a symmetrical parasitic patch, and designing a feeding circuit, it is possible to provide an antenna capable of smooth reception without interference from each other in the triple band. Therefore, it is possible to provide an antenna capable of receiving T-DMB (L-Band) in various places around the world.

As described above, the present invention has been described by way of limited embodiments and drawings, but the present invention is not limited to the above-described embodiments, which can be variously modified and modified by those skilled in the art to which the present invention pertains. Modifications are possible. Accordingly, the spirit of the present invention should be understood only by the claims set forth below, and all equivalent or equivalent modifications thereof will belong to the scope of the present invention.

FIG. 1 is an enlarged view of an antenna and a ground part of an antenna having a memetic parasitic patch according to an exemplary embodiment of the present invention.

2 is an enlarged view of a first radiator antenna according to an embodiment of the present invention.

3 is an enlarged view of a second radiator antenna according to an embodiment of the present invention.

4 is a view for explaining the return loss of the antenna provided with a symmetric parasitic patch in an embodiment of the present invention.

FIG. 5 is a diagram for describing a radiation pattern of an antenna provided with a symmetrical parasitic patch according to one embodiment of the present invention.

FIG. 6 is a diagram for explaining gain characteristics of an antenna provided with a memetic parasitic patch according to an embodiment of the present invention.

<Explanation of symbols for the main parts of the drawings>

110: first radiator antenna 120: second radiator antenna

130: ground portion 131: feeding point (feeding point)

132: lumped element 133: matching stub

Claims (15)

A first radiator antenna to which a symmetrical parasitic patch is attached to an upper end of a rod-shaped FR4 substrate; And A second radiator antenna installed spaced apart from the first radiator antenna by a predetermined distance, and having a symmetrical parasitic patch attached to an upper end of a rod-shaped FR4 substrate; Triple-band antenna having a symmetrical parasitic patch comprising a. The method of claim 1, Further comprising a system ground including a feeder, The feed section, A matching stub for impedance matching; And Lumped element located on feed line Triple-band antenna having a memetic parasitic patch comprising a. The method of claim 2, The system ground is A triple band antenna having a membranous parasitic patch, comprising a FR4 substrate having a thickness of 1.6 mm, a dielectric constant of 4.4, a width of 150 mm, and a length of 110 mm. The method of claim 1, The first radiator antenna and the second radiator antenna, The triple band antenna provided with a memetic parasitic patch, characterized in that the whole including the first radiator antenna and the second radiator antenna is 5mm in width. The method of claim 1, The first radiator antenna, Rod-shaped FR4 substrates; A main radiator attached to one side of the FR4 substrate and having a lower end serpentine; At least one concentrated inductor attached to a lower end of the main radiator; Memphid-type parasitic patch attached to the upper end of the main copy; And U-shaped parasitic patch attached to the lower end of the other side of the FR4 substrate Triple-band antenna having a symmetrical parasitic patch comprising a. The method of claim 5, The main copy is, From the bottom edge of the FR4 substrate to the top edge, The lower end of the three-band antenna having a symmetrical parasitic patch, characterized in that the Hangul consonant dish shape is symmetrical and repeated. The method of claim 6, One dishing shape of the lower end portion, Triple-band antenna having a memetic parasitic patch, characterized in that the vertical length of 10mm. The method of claim 5, The memetic parasitic patch, A triple-band antenna having a memetic parasitic patch attached to the upper end of the main radiator in the form of two cells and connected to the main radiator through three via holes. The method of claim 8, The memetic parasitic patch, Triple-band antenna with a meme-dore parasitic patch, characterized in that the vertical length of 20mm. The method of claim 1, The second radiator antenna, Rod-shaped FR4 substrates; A main radiator attached to both sides of the FR4 substrate, the main radiator having a curved upper end portion; Parasitic patches attached to lower ends of both sides of the FR4 substrate; And One or more memetic parasitic patches attached to the upper end of one side of the FR4 substrate Triple-band antenna having a symmetrical parasitic patch comprising a. The method of claim 10, The main copy is From the bottom edge of the FR4 substrate to the top edge, The upper end of the triple-band antenna having a symmetrical parasitic patch, characterized in that the Hangul consonant dish shape is symmetrical and repeated. The method of claim 11, One dishing shape of the upper end, Triple-band antenna having a memetic parasitic patch, characterized in that the vertical length of 10mm. The method of claim 10, The memetic parasitic patch, A triple-band antenna having a memetic parasitic patch attached to an upper end of the main radiator in the form of six cells and connected to the main radiator through eleven via holes. The method of claim 13, The memetic parasitic patch, Triple-band antenna with a meme-dore parasitic patch, characterized in that the vertical length of 60mm. The method of claim 10, Parasitic patches attached to the lower ends of both sides, Triple-band antenna with a meme-dore parasitic patch, characterized in that the vertical length of 25mm.

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