KR100856957B1 - Internal antenna - Google Patents

Abstract

The present invention provides a built-in antenna of the mobile communication terminal. Polyhedral dielectric blocks; A first radiator pattern formed on one side of the dielectric block; A second radiator pattern formed on the other side of the dielectric block; A conductive pad formed on any one of side surfaces of the first and second radiator patterns, the conductive pad being spaced apart from the radiator pattern of the corresponding side surface; And a long hole vertically penetrating from one side of the dielectric block to the other side of the dielectric block and electrically connecting the first radiator pattern and the second radiator pattern. The built-in antenna of the present invention having such a configuration can utilize the volume of the dielectric to the maximum, thereby making it possible to miniaturize the antenna.

Built-in type, antenna, inductive coupling, conductive pattern, long hole

Description

 Internal antenna

1 is a structural diagram illustrating a conventional built-in antenna structure.

2 is a perspective view for explaining in detail the built-in antenna according to an embodiment of the present invention.

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

200: dielectric block 210a: Chapter 1 hole

210b: Chapter 2 hole 220a: Feeding part

220b: grounding portion 220: conductive pad

230: first radiator pattern 240: second radiator pattern

250: via hole

The present invention relates to an embedded antenna applied to a mobile communication terminal, and more particularly, to form a plurality of long holes penetrating through the dielectric block, and to electrically connect the adjacent long holes by printing or filling the respective long holes with a conductive material. The present invention relates to a built-in antenna of a mobile communication terminal capable of miniaturizing an antenna by maximizing the volume of a dielectric by forming a radiation line so that the connected length can have a predetermined electrical length.

At present, due to the rapid development of communication technology, various kinds of mobile communication services such as cellular, PCS and PHS are being implemented. Mobile communication terminals are being developed with the aim of miniaturization, multifunction, light weight, and low power. This trend is equally required in the antenna, which is one of the main components of the mobile communication terminal.

The antenna in the mobile communication terminal plays the role of a key component to determine the call quality and the beginning and end of the signal input and output.

Antennas for mobile communication terminals can be largely divided into internal and external types. The external antenna currently used generally is installed to protrude outside the mobile communication terminal, and is applied in various forms.

These antennas have the advantage of obtaining high gain, but they are non-directional and have a poor SAR (Specific Absorption Rate) characteristic. In addition, due to the form protruding to the outside, the problem of spoiling the appearance of the terminal and occupy a large volume has occurred.

In order to solve the above problems, it is possible to reduce the size of the antenna by increasing the electrical length of the antenna radiating element by using a high dielectric material as a whole of the base of the antenna, and to adopt the built-in antenna which can be mounted on the printed circuit board inside the terminal. It's growing.

However, in general, in the case of an antenna mainly used for wireless communication or the like, it basically has a characteristic of resonating at λ / 2 and λ / 4 lengths. Due to the development of technology, the demand for miniaturization of antennas, which are essential for wireless communication, is increasing, but due to the characteristics of antennas resonating at the λ / 2 and λ / 4 lengths of use frequency, Miniaturization has its limits. Common methods for miniaturizing antennas include increasing the electrical length of the antenna using ferroelectrics, and increasing the physical length of the antenna by bending or dividing the antenna into various shapes.

1 is a structural diagram for explaining an antenna structure having a conventional antenna element.

As shown in FIG. 1, in the conventional built-in antenna illustrated in FIG. 1, a feed electrode 110 is formed on one side of a dielectric block 100, and the feed electrode is formed on an upper surface of the dielectric block 100. The antenna pattern 120 connected to the 110 is formed in a meander line structure. Here, the antenna pattern 120 has a length of λ / 2 and λ / 4 of a reception or transmission frequency.

However, in the conventional chip antenna, since the antenna pattern is formed as a meander line only on the surface of the dielectric block, particularly, the upper surface, the upper surface of the dielectric block must be made of a relatively large area in order to realize a desired electrical length. The same chip antenna is difficult to miniaturize.

In addition, since the conventional internal antenna has a limited area that can be formed on the dielectric surface, it is not easy to design a multi-band antenna such as a dual band or triple band, and the size of the internal antenna is reduced. There are a lot of problems with this.

SUMMARY OF THE INVENTION The present invention has been proposed to solve the above-mentioned problems, and by forming a long hole through the dielectric block to maximize the device volume of the dielectric, it is possible to further miniaturize the same resonant frequency, multi-chip chip antenna The present invention provides an internal antenna that is easy to design.

The built-in antenna of the mobile terminal according to the present invention for solving the above problems is a dielectric block of a polyhedron; A first radiator pattern formed on one side of the dielectric block; A second radiator pattern formed on the other side of the dielectric block; A conductive pad formed on any one of side surfaces of the first and second radiator patterns, the conductive pad being spaced apart from the radiator pattern of the corresponding side surface; And a long hole vertically penetrating from one side of the dielectric block to the other side of the dielectric block and electrically connecting the first radiator pattern and the second radiator pattern.

In particular, the conductive pad, both ends are bent to the outside, one end is formed of a feed portion and the other end is formed of a ground portion, preferably formed on one side of the dielectric block.

In addition, it is preferable that the plurality of long holes are formed spaced apart from each other.

In addition, it is preferable that the radiator pattern formed on any one side on which the conductive pad is formed is inductively coupled to the conductive pad at a predetermined distance from each other.

The present invention made as described above will be described in detail with reference to the accompanying drawings. The same reference numerals are used for the same configurations as the prior art, and repeated descriptions, well-known functions that may unnecessarily obscure the subject matter of the present invention, and detailed descriptions of the configurations will be omitted. Embodiments of the present invention are provided to more completely describe the present invention to those skilled in the art. Accordingly, the shape and size of elements in the drawings may be exaggerated for clarity.

Figure 2 is a perspective view for explaining in detail the built-in antenna using an inductively coupled feeding method according to an embodiment of the present invention.

Built-in antenna according to the present invention, the polyhedral dielectric block 200, the first radiator pattern 230 formed on one side of the dielectric block, the second radiator pattern 240 formed on the other side opposite to the one side, The conductive pad 220 is formed on any one of the side surfaces of the first and second radiator patterns, spaced apart from the radiator pattern of the side surface, vertically penetrates from one side of the dielectric block to the other side of the dielectric block, It is composed of a long hole 210 and a via hole 250 for electrically connecting the first radiator pattern and the second radiator pattern.

The dielectric block 200 is formed by including either dielectric or magnetic material, wherein the polyhedron includes a cuboid, a cylindrical body, and the like.

As shown in FIG. 2, the long hole 210 penetrates from one side of the dielectric block 200 to the other side of the dielectric block 200 with a length A longer than the width B, and the inside of the long hole 210 is printed with a conductive material. It is filled and formed. Therefore, it is formed in a structure that can increase the gain characteristics of the antenna by maximizing the volume of the dielectric block 200. The long hole 210 may be formed as a straight hole (-) in the form of, as in the embodiment of the present invention, in another form, a needle hole (b), Dija (c), and rile (d) shape If it is possible to make the most of the volume of the dielectric block 200 through the 210 will be applicable to the present invention. In addition, if the shape of the hole can be considered by those skilled in the art within the scope that can achieve the object of the present invention will be applicable. In addition, in the embodiment of the present invention, the two long holes 210 are taken as an example, but the number of the long holes 210 described above may vary depending on the resonance frequency and bandwidth of the antenna to be implemented, and the long holes 210 may be used. Of course, the length (A), width (B) and height (C) of may vary depending on the resonance frequency and bandwidth of the antenna to be implemented.

The long hole 210 is formed as a hole having a length in the dielectric block 200 by punching a plurality of via holes in succession. Implementing the resonant frequency to be implemented through the long hole 210, the manufacturing process is more than to implement the electrical resonance length of the antenna by connecting a plurality of via holes, the inside of which is printed or filled with a conductive material through a conductive connection pattern, respectively In addition to being easy, it is possible to form a wide radiation line through a volume formed on the inner surface of the long hole 210, it is possible to obtain a resonant frequency having a wider band at the same resonant frequency to be implemented.

The conductive pads 220 are formed in a concave-shaped structure as a whole, and both ends of the conductive pads 220 are bent to the outside to be formed of a conductive material on the lower surface of the dielectric block 200. The bent one end of the conductive pad 220 is provided with a feed part 220a and the other end is formed with a ground part 220b. The conductive pad 220 may be applicable to the triangular and square shapes as well as the yaw shape. In addition, those skilled in the art to which the present invention pertains, the conductive pad 220 and the first radiator pattern (in accordance with the change in the area of the inside of the feed portion 220 formed on one side of the dielectric block 200) By adjusting the mutual inductance by changing the distance to 230, it can be leaked out through the present specification that the resonance frequency to be implemented by adjusting the real part of the impedance of the antenna can be adjusted.

The first radiator pattern 230 is formed as a conductive pattern by being spaced apart from each other by a predetermined distance on the bottom surface of the dielectric block 200 on which the conductive pad 220 is formed. Is connected to one end of the), the other end is formed as a ground end, the first radiator pattern 230 and the conductive pad 220 is inductively coupled to each other.

The first radiator pattern 230b is a conductive pattern for horizontal connection connecting the adjacent long hole 210b and the via hole 250. One end of the lower end of the 250 is electrically connected to each other to have a predetermined length and form a radiation line.

The second radiator pattern 240 is a conductive pattern formed on an upper surface of the dielectric block, and the second radiator pattern 240a is a horizontal connection pattern for electrically connecting the first long hole 210a and the second long hole 210b to each other. It has a predetermined length to form a radiation line, the second radiator pattern 240b is connected to one side of the upper end of the via hole 250 to have a predetermined length and form a radiation line. In addition to the long hole 210, an additional via hole 250 is formed in the dielectric block 200 to finely adjust the resonance frequency to be realized by electrically connecting the first radiator pattern 230b and the second radiator pattern 240b to each other. It can be easier to do.

Meanwhile, in the exemplary embodiment of the present invention, the second radiator pattern 240 is formed on the upper surface of the dielectric block 200, but is not limited thereto and may be formed on the side surface adjacent to the first radiator pattern 230. It goes without saying that modifications can be made by those skilled in the art to which the present invention pertains.

The conductive pad 220, the first radiator pattern 230, and the second radiator pattern 240 may be stacked on the surface of the dielectric block 200 by screen printing or dipping. In addition, in one embodiment of the present invention, a single dielectric block is illustrated, but may be a dielectric block structure in which a plurality of dielectric sheets are stacked.

Through this structure, it is possible to implement a longer resonance length in the same volume of dielectric blocks, to effectively integrate the pattern in the same space as compared to the conventional form, and to provide a longer electric radiation line.

As mentioned above, although one preferred embodiment of the present invention has been illustrated and described, the present invention is not limited to the specific embodiments described above, and the present invention belongs to the present invention without departing from the gist of the present invention as claimed in the claims. Various modifications can be made by those skilled in the art, and these modifications should not be understood individually from the technical idea or the prospect of the present invention.

As described above, the built-in antenna according to the present invention can implement a longer resonance length in the same volume of dielectric blocks, and can directly direct the pattern in the same space compared to the conventional form, and longer electrical resonance It is possible to provide a radiation line having a length.

Claims (4)

Polyhedral dielectric blocks; A first radiator pattern formed on one side of the dielectric block; A second radiator pattern formed on the other side of the dielectric block; A conductive pad formed on one side of the side surfaces of which the first and second radiator patterns are formed and spaced apart from the radiator pattern of the side surface; And And a long hole that vertically penetrates from one side of the dielectric block to the other side of the dielectric block and electrically connects the first radiator pattern and the second radiator pattern. The method according to claim 1, The conductive pad, Both ends are bent to the outside, one end is formed of the feed portion and the other end is formed of the ground portion, built-in antenna, characterized in that formed on one side of the dielectric block. The method according to claim 1, The long hole is a built-in antenna, characterized in that formed in plurality apart from each other. The method according to claim 1, The radiator pattern formed on any one side of the conductive pad is formed, the antenna is inductively coupled to the conductive pad spaced apart from each other by a predetermined distance.

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