KR101077139B1 - Embeded VHF antenna with magneto-dielectric block - Google Patents

Abstract

The disclosed microwave internal antenna includes a magnetic dielectric block having a flat bottom surface, and having mounting pads at both ends of the bottom surface of the block, the magnetic dielectric block having a first radiator pattern wrapped around the block; And a printed circuit board having two soldering pads formed on the upper surface thereof to which the mounting pads are bonded, and having a second radiator pattern having a shape along the outline of the magnetic dielectric block bonded to the soldering pads on the lower surface thereof. It is possible to provide an ultra-short internal antenna capable of receiving FM radio without impairing the miniaturization of the terminal even when applied to a mobile communication terminal.

Microwave, Built-In Antenna, Magnetic Dielectric Block, Radiator Pattern, Coupling, Return Loss

Description

Embedded antenna for microwaves using magnetic dielectric blocks {Embeded VHF antenna with magneto-dielectric block}

The present invention relates to a microwave antenna, and more particularly, to a built-in antenna for microwaves capable of receiving FM radio without impairing the miniaturization of the terminal even when applied to a mobile communication terminal.

Since mobile terminals have a strong characteristic of being a mobile device that is always carried, there are many other additional functions beyond the original functions of making and receiving calls according to the demands of consumers, such as a camera function, a DMB function, and an MP3. It is evolving into a multi-media device that can provide various contents with functions, video player function, FM radio function and Bluetooth function. In other words, a user watches a movie, listens to music, and communicates with a user through a single terminal called a mobile communication terminal.

One of the essential components of such a mobile communication terminal is an antenna, and the physical size of the antenna is closely related to the frequency of the use band. In other words, the longer the length of the frequency wavelength, the larger the size of the antenna. For FM radio using the VHF band, the band 87.5 MHz to 108 MHz is used, in which case the wavelength in the free space reaches 306 cm. Therefore, since the FM antenna having a length of 1/4 wavelength, which is the minimum length of the antenna, reaches a length of about 76 cm, it cannot be embedded in a mobile communication terminal unless a special configuration is adopted.

In order to solve this problem, the earphone is used as an antenna when listening to the FM broadcast by the mobile communication terminal, and the wire of the earphone is used as an antenna, or a dipole antenna which is commonly seen as an external device. There is a way to connect. However, the external dipole antenna method is inconvenient to carry the FM antenna separately in the mobile communication terminal where portability is important. Recently, the widely used Bluetooth wireless communication terminal has no FM radio broadcasting because there is no cable in the earphone. To listen, you need to use a separate wired earphone.

In addition, the ceramic antenna of the high dielectric constant, which is a conventional technique used for miniaturization of the antenna, has a problem in that the bandwidth of the high dielectric constant is narrowed, so that the antenna of the FM band cannot be implemented.

After all, due to the above problems, even if applied to a mobile communication terminal does not hinder the miniaturization of the terminal, there is a demand for the development of a built-in microwave antenna for microwave reception capable of receiving FM radio.

SUMMARY OF THE INVENTION The present invention has been made to solve the above-mentioned problems in the prior art, and it is an object of the present invention to provide a built-in antenna for microwaves capable of receiving FM radio without impairing the miniaturization of the terminal even when applied to a mobile communication terminal.

Another object of the present invention is to provide a built-in antenna capable of receiving an FM band, and to provide a built-in antenna for microwaves having excellent matching performance by moving the resonance frequency of the antenna to a low frequency band and having a high return loss. do.

According to another aspect of the present invention, there is provided a built-in antenna for microwave, comprising: a magnetic dielectric block having a bottom surface having a flat block shape, and mounting pads at both ends of the bottom surface of the block, the first dielectric pattern having a circumference around the block; And a printed circuit board having two soldering pads formed on the upper surface thereof to which the mounting pads are bonded, and a second radiator pattern having a shape along the outline of the magnetic dielectric block bonded to the soldering pads on the lower surface thereof. .

At this time, the magnetic permeability of the magnetic dielectric block is preferably in the range of 1.5 to 4.0 times the dielectric constant.

And preferably, the second radiator pattern is composed of a pattern forming a closed curve.

In addition, the second radiator pattern may have a U-shape in which either side of the second radiator pattern corresponding to the position of the soldering pad is opened.

Meanwhile, in the exemplary embodiment of the present invention, any one of the two soldering pads forms an antenna input line.

In this case, the antenna input line is a CoPlanar Waveguide with Ground-plane (CPWG) line.

In addition, the printed circuit board may be configured of a rigid printed circuit board or a flexible printed circuit board.

The built-in antenna for microwaves of the present invention having the above configuration has a resonance frequency of the antenna by coupling the first radiator pattern formed on the magnetic dielectric block and the second radiator pattern spaced apart from the first radiator pattern by the thickness of the printed circuit board. In addition to being moved to a low frequency band capable of receiving the FM band, there is an advantage that it can be miniaturized to be embedded in a mobile communication terminal.

In addition, the shape of the second radiator pattern has the shape of a square ring or a U-shaped hollow inside thereof, thereby greatly increasing the return loss, thereby improving the matching performance of the antenna.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

In the description of one embodiment of the present invention, descriptions of well-known configurations that will be apparent to those skilled in the art will be omitted so as not to obscure the subject matter of the present invention. In addition, when referring to the drawings it should be considered that the thickness of the lines or the size of the components shown in the drawings may be exaggerated for clarity and convenience of description.

Meanwhile, terms used to describe one embodiment of the present invention and define relative positions of front, rear, left and right, and the like used on the basis of the accompanying drawings. It should be noted, however, that such definitions of relative positions may be altered in an equivalent arrangement without changing the essential parts of the invention.

As shown in FIGS. 1 to 3B, the microwave antenna 10 according to the present invention includes a magnetic dielectric block 100 having a rectangular parallelepiped shape and a printed circuit board 200 on which the magnetic dielectric block 100 is mounted. It includes.

Referring to FIG. 2, the structure of the magnetic dielectric block 100 will be described in more detail. The mounting pads 110 are provided at both ends of a block having a flat bottom surface, for example, a block having a rectangular parallelepiped shape, and a magnetic dielectric block. The first radiator pattern 120 is formed to surround the circumference of the 100. Herein, the magnetic dielectric block 100 refers to a dielectric block having a permeability greater than that of the dielectric constant, thereby realizing a wider bandwidth than a conventional high dielectric constant dielectric. The magnetic permeability and permittivity values of the magnetic dielectric block 100 are preferably set so that the permeability is in the range of 1.5 to 4.0 times the permittivity in consideration of both the miniaturization of the antenna according to the permittivity and the implementation of a wide bandwidth according to the permeability. Do.

In the printed circuit board 200 on which the magnetic dielectric block 100 is mounted, two soldering pads 210 are formed on the upper surface of which the mounting pad 110 formed on the lower surface of the magnetic dielectric block 100 is bonded by soldering. The second radiator pattern 220 along the outline of the magnetic dielectric block 100 bonded to the soldering pad 210 and mounted thereon is formed on the bottom surface thereof. Therefore, the second radiator pattern 220 is coupled away from the first radiator pattern 120 by the thickness of the printed circuit board 200. Since the resonance frequency decreases by the area and the length of the second radiator pattern 220. It becomes possible to function as an FM antenna. The printed circuit board 200 is composed of a rigid printed circuit board or a flexible printed circuit board.

4 shows that the first radiator pattern 120 is formed on the magnetic dielectric block 100 having a dielectric constant of about 7.2 and the permeability of about 13.5, but the second radiator pattern 220 is not formed on the bottom surface of the printed circuit board 200. In this case, the frequency characteristics are shown. Compared with FIG. 5 showing the frequency characteristics when the second radiator pattern 220 is formed, it can be seen that the present invention has suitable characteristics as an FM antenna. That is, when the second radiator pattern 220 is absent, the resonant frequency is 121 MHz, which is out of the FM band. In the present invention, in which the second radiator pattern 220 is formed, the resonant frequency is lowered to have a value of 97.4 MHz. Have Therefore, the present invention including the second radiator pattern 220 may function as an FM antenna.

On the other hand, the shape and size of the second radiator pattern 220 is not only related to the downward frequency of the resonance frequency but also affects the matching of the antenna. Good matching of the antenna can be assessed by return loss. Return loss refers to a value obtained by converting a reflection coefficient, which is an index calculated from the input voltage to the reflection voltage ratio, into a logarithmic scale of power at a connection stage. The small value means that the matching of antenna is good. Referring back to the graph shown in FIG. 5, when the rectangular second radiator pattern 220 is formed, it can be seen that the return loss at the resonance frequency is about -6.7 kHz, so that the efficiency as an antenna is not excellent. In other words, by applying the magnetic dielectric block 100 having a magnetic permeability greater than the dielectric constant to realize a wide bandwidth, and further, by inducing the resonance frequency downward by the formation of the second radiator pattern 220, the basic condition as an FM antenna was satisfied. There is still some improvement in the efficiency of the FM antenna.

6 shows another embodiment of the present invention in which the efficiency of the FM antenna is improved by forming the second radiator pattern 220 in a closed curved pattern, for example, a rectangular ring. When the ring-shaped second radiator pattern 220 forming the closed curve is applied, the resonance frequency is 97.65 MHz, which is also in the FM band, and the return loss is -27.7 ㏈, which is approximately lower than that of the rectangular second radiator pattern 220. It can be seen that the efficiency improvement of 21 kHz was achieved. The ring-shaped second radiator pattern 220 constituting the closed curve may be somewhat deformed during the matching process. For example, any one of both sides corresponding to the position of the soldering pad 210 may be changed as illustrated in FIG. 3B. It is also possible to apply the U-shaped second radiator pattern 220 that is open.

Meanwhile, in the exemplary embodiment of the present invention, any one of the two soldering pads 210 forms the antenna input line 230. In this case, the antenna input line 230 is preferably a CoPlanar Waveguide with Ground-plane (CPWG) line.

While the preferred embodiments of the present invention have been illustrated and described above, it will be apparent to those skilled in the art that the present embodiments may be modified without departing from the spirit or spirit of the present invention. Therefore, the scope of the present invention will be defined by the appended claims and equivalents thereof.

1 is a perspective view showing the overall appearance of a built-in antenna for microwaves according to the present invention.

2 is a view showing a detailed view of the magnetic dielectric block and the first radiator pattern formed thereon.

3A is a view illustrating a top surface of a printed circuit board on which soldering pads are formed.

3B illustrates a bottom surface of a printed circuit board on which a second radiator pattern is formed.

4 is a graph showing a resonance frequency and a return loss in the absence of the second radiator pattern.

5 is a graph showing a resonance frequency and a return loss when a rectangular second radiator pattern is formed.

FIG. 6 is a graph showing a resonance frequency and a return loss when the second ring pattern having a rectangular ring shape is formed. FIG.

Description of the Related Art

10: built-in antenna for microwave

100 magnetic dielectric block 110 mounting pad

120: first radiator pattern 200: printed circuit board

210: soldering pad 220: second radiator pattern

230: antenna input line

Claims (7)

A magnetic dielectric block having a bottom surface formed in a flat block shape, mounting pads being provided at both ends of the bottom surface of the block, and having a first radiator pattern surrounding the block; And A printed circuit board having two soldering pads formed thereon to which the mounting pads are bonded, and a second radiator pattern having a shape along an outline of the magnetic dielectric block bonded and mounted to the soldering pads; ≪ / RTI > The second radiator pattern is an embedded antenna for microwaves, characterized in that the pattern forming a closed curve. A magnetic dielectric block having a bottom surface formed in a flat block shape, mounting pads being provided at both ends of the bottom surface of the block, and having a first radiator pattern surrounding the block; And A printed circuit board having two soldering pads formed thereon to which the mounting pads are bonded, and a second radiator pattern having a shape along an outline of the magnetic dielectric block bonded and mounted to the soldering pads; ≪ / RTI > The second radiator pattern has a built-in antenna for microwaves, characterized in that having a U-shape in which either side of the sides corresponding to the position of the soldering pad is open. The method according to claim 1 or 2, And the magnetic permeability of the magnetic dielectric block is in the range of 1.5 to 4.0 times the permittivity. delete The method according to claim 1, The built-in antenna for microwaves, characterized in that any one of the two soldering pads to form an antenna input line. The method according to claim 5, And the antenna input line is a coplanar waveguide with ground-plane (CPWG) line. The method according to claim 1, The printed circuit board is an embedded antenna for microwaves, characterized in that the rigid printed circuit board or flexible printed circuit board.

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