KR20090124252A - Built-in rfid reader antenna used in mobile communication terminal - Google Patents

Abstract

PURPOSE: An internal RFID reader antenna for a mobile communication terminal is provided to easily obtain desired tag information by forming an electric field into a horizontal direction about a ground surface. CONSTITUTION: A first radiation device part(200) includes a first feeding part, a first short-circuit part, a first radiation pattern, and a second radiation pattern. The first feeding part and the first short-circuit part are connected to an edge part of one end of a ground part(100). The first radiation pattern is extended from the first feeding part and the first short-circuit part. The second radiation pattern is extended from the first radiation pattern. A first parasitic device part(300) includes a second short-circuit part, a third radiation pattern, and a fourth radiation pattern. The second short-circuit part is connected to a central part of one end of the ground part. The third radiation pattern is extended from the second short-circuit part, and is symmetrical to the first radiation pattern. The fourth radiation pattern is extended from the third radiation pattern, and is symmetrical to the second radiation pattern.

Description

Built-in RFID reader antenna used in mobile communication terminal {Built-in RFID reader antenna used in mobile communication terminal}

The present invention relates to a built-in RFID reader antenna used in a mobile communication terminal, and more particularly, in the UHF band by configuring the radiating element and the parasitic element connected to the ground to have a omnidirectional radiation pattern perpendicular to the ground plane. The present invention relates to an embedded RFID reader antenna used for a mobile communication terminal collecting only desired tag information.

Conventional RFID systems are used in many fields, such as museum tours, library libraries, logistics, counterfeit discrimination, security, movie information, and ticketing services, and are applied to various technologies in the ubiquitous society. This is rapidly developing.

The technology combined with the mobile communication terminal in the RFID system is rapidly developing, and there are typical techniques related to tag recognition. Among them, FIG. 1 is an RFID reader antenna for collecting conventional tag information. The RFID reader antenna includes a ground portion and a radiating element portion, and when the radiating element portion is connected to the ground portion, current flows as shown by the arrow.

Accordingly, the electric field is formed perpendicular to the ground plane as shown by the dotted lines A and B. When the electric field is formed vertically, as shown in FIG. 2, a large number of tags are distributed. The tag (tag 1, tag 2, tag 3, tag 4 in FIG. 2) is in the recognition range and when obtaining the tag information in the recognition range, an interference problem occurs so that only desired tag information cannot be obtained. There was this.

SUMMARY OF THE INVENTION An object of the present invention for solving the above problems is to provide an embedded RFID reader antenna for use in a mobile communication terminal having a radiating element part and a parasitic element part in a ground part so as to have a omnidirectional radiation pattern with respect to a vertical plane in a UHF band. There is this.

According to an embodiment of the present invention for achieving the above object is a built-in RFID antenna used in the mobile communication terminal is a ground portion, the first feed portion connected to the vertical portion of the edge of one end of the ground portion; And a first short circuit portion formed therein, a first radiation pattern of a meander line shape is formed to extend with the first feed portion and the first short circuit portion, and a second radiation pattern formed with a second radiation pattern vertically downwardly extending with the first radiation pattern. A first radiating element portion and a second shorting portion and a second shorting portion which are vertically connected to the central portion of the end of the ground portion to which the first feeding portion and the first shorting portion are connected are formed to be symmetrical with the first radiation pattern. A first parasitic element portion formed with a fourth radiation pattern formed with a third radiation pattern and symmetrically with the second radiation pattern so as to extend with the third radiation pattern What is done is taken as a solution.

As described above, the present invention has the effect of solving the interference problem caused when the reader acquires the tag information by the omni-directional radiation pattern on the vertical plane.

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

3 is a perspective view of an embedded RFID reader antenna used in a mobile communication terminal according to the present invention, wherein the embedded RFID reader antenna 10 is a ground part 100 which is grounded and a corner portion at one end of the ground part 100. The first feed portion 210 and the first short circuit portion 220 are formed in the vertically connected to the first radiation of the meander line type to extend with the first feed portion 210 and the first short circuit portion 220 A first radiation element unit 200 formed of a second radiation pattern 240 formed in a pattern 230 and extending downwardly perpendicularly to the first radiation pattern 230, and the first feed unit 210. The first short circuit portion 220 is symmetrical with the first radiation pattern 230 so as to extend to the second short circuit portion 310 and the second short circuit portion 310 vertically connected to the central portion of the end of the ground portion to which the first short circuit portion 220 is connected. The third radiation pattern 320 is formed and the second radiation pattern 320 to extend with the second The first parasitic element portion 300 formed by the fourth radiation pattern 330 formed to be symmetrical with the radiation pattern 240 is a solution.

In more detail, the ground part 100 is vertically connected to the first feeding part 210 of the first radiating element part 200 as well as the first shorting part 220 of the first radiating element part 200. ) Is vertically connected, and in this way the first feed section 210 and the first short-circuit 220 are connected, it is preferably connected near the end edge of the ground portion (100).

In addition, the ground part 100 is vertically connected to the second shorting part 220 of the first parasitic element part 300, and thus, the second shorting part 220 is connected to the ground part 100. ) Is preferably connected to the central portion of the end.

In addition, the substrate for forming the ground portion 100 is an epoxy resin material.

The first radiating element part 200 has a first feeding part 210 and a first shorting part 220 formed upwardly at a predetermined interval and are disposed on the first feeding part 210 and the first shorting part 220. A first radiation pattern 230 having a meander line shape is formed to extend, and the second radiation pattern 240 is formed to be perpendicular to the first radiation pattern 230 so as to extend downward. The radiating element part 200 is preferably a monopole type as well as a PIFA type.

The first parasitic element part 300 has a ground part 100 to which a second short circuit part 310 is connected to the first feed part 210 and the first short circuit part 220 of the first radiating element part 200. A third radiation pattern 320 is formed in the vertical portion of the end of the end portion and is formed to be symmetrical with the first radiation pattern 230 of the radiation element portion 200 to extend to the second short circuit portion 310. The fourth radiation pattern 330 is formed to be symmetrical with the second radiation pattern 240 in a vertical direction extending from the third radiation pattern 320.

As described above, the present invention configured as described above shows an electric field for obtaining only a desired tag from among a plurality of tags, which will be described in more detail with reference to FIG. 5.

FIG. 5 is a flowchart illustrating a current of an embedded RFID reader antenna used in a mobile communication terminal according to the present invention. In the case of the ground unit 100, the current flows in the case of the ground element 100 and the radiating element unit 200 and the parasitic element. Current flows in the direction in which the unit 300 is configured, and the radiating element unit 200 and the parasitic element unit 300 flow in a direction opposite to each other as shown.

That is, the current directions of the radiating element portion 200 and the parasitic element portion 300 are in phase out of phase with each other, so that the electric field is horizontally formed as a dotted line between C and D shown. It is formed horizontally with respect to the floor surface.

Therefore, as shown in FIG. 4, information of only a desired tag can be obtained from a plurality of tags.

6 is a configuration diagram of a second radiating element portion and a second parasitic element portion according to another embodiment of the present invention, wherein the second radiating element portion 400 and the second parasitic element portion 500 are shown in FIG. 3. As described above, the second feeding part 410 and the third shorting part 420 of the second radiating element part 400 are connected to one end of the ground part 100, but are connected to the center of the ground part end part. The fourth shorting part 510 of the second parasitic element part 500 is also connected to the central part spaced apart from the second feeding part 410 by a predetermined distance.

In this configuration, current flows from the left to the right. That is, it flows in phase and the electric field is formed in the horizontal direction as shown in FIG.

Therefore, as shown in FIG. 4, only desired tag information is received.

FIG. 7 is a diagram illustrating a configuration of a radiating element part and a parasitic element part according to another embodiment of the present invention, wherein the third radiating element part 600 and the third parasitic element part 700 are grounded as shown in FIG. 4. The third feed part 610 and the fifth short circuit part 620 of the third radiating element part 600 are connected to one side edge of one end of the ground part, but are connected to one end of the part. The sixth short circuit portion 710 of the three parasitic element portion 700 is connected to the other side edge portion.

In this configuration, current flows from the left to the right. That is, it flows in phase and the electric field is formed in the horizontal direction as shown in FIG.

Therefore, as shown in FIG. 4, only desired tag information is received.

8 is a graph showing the VSWR of the embedded RFID reader antenna used in the mobile communication terminal according to the configuration of FIG. 3, and the measured impedance bandwidth VSWR <3 is 21 MHz.

The impedance bandwidth satisfies the mobile RFID service band in Korea.

FIG. 9 is a graph illustrating a radiation pattern of an embedded RFID reader antenna used in the mobile communication terminal according to the configuration of FIG. 3. In the illustrated radiation pattern, the maximum gain of a general mobile communication terminal is -0.37 dBi at a resonance frequency.

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features.

Therefore, it is to be understood that the above description is only one embodiment, illustrative, and not restrictive. The scope of the present invention is shown by the following claims rather than the detailed description, and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included in the scope of the present invention. do.

1 is a RFID reader antenna for collecting conventional tag information

2 is an exemplary diagram in which a conventional RFID reader antenna acquires a tag.

3 is a perspective view of a built-in RFID reader antenna used in a mobile communication terminal according to the present invention

4 is a diagram illustrating obtaining desired tag information according to the present invention.

5 is a flow chart of an embedded RFID reader antenna used in a mobile communication terminal according to the present invention.

6 is a configuration diagram of the radiating element and parasitic element according to another embodiment of the present invention

7 is a configuration diagram of the radiating element portion and the parasitic element portion according to another embodiment of the present invention

8 is a VSWR graph of an embedded RFID reader antenna used in a mobile communication terminal according to the configuration of FIG.

9 is a radiation pattern graph of an embedded RFID reader antenna used in a mobile communication terminal according to the configuration of FIG.

* Explanation of Signs of Major Parts of Drawings *

10: Built-in RFID reader antenna used for mobile communication terminal

100: ground portion 200: first radiating element portion

210: first feeder 220: first short circuit

230: first radiation pattern 240: second radiation pattern

300: first parasitic element 310: second short circuit

320: third radiation pattern 330: fourth radiation pattern

400: second radiating element 410: second feeding part

420: third short circuit 500: second parasitic element

620: fifth short circuit 700: sixth short circuit

Claims (7)

A ground portion that is grounded; A first feed part and a first short circuit part which are vertically connected to an edge portion of one side end of the ground part are formed, and a first radiation pattern of a meander line shape is formed to extend with the first feed part and the first short part; A first radiation element portion formed by a second radiation pattern extending downwardly perpendicularly to the first radiation pattern; And A second short circuit portion which is vertically connected to the central portion of the end of the ground portion to which the first feed portion and the first short circuit portion are connected, and a third radiation pattern which is formed symmetrically with the first radiation pattern to extend to the second short circuit portion are formed. And a first parasitic element portion formed of a fourth radiation pattern symmetrically formed with the second radiation pattern so as to extend with the third radiation pattern. The method according to claim 1, The electric current of the ground portion flows toward the first radiating element portion and the first parasitic element portion, and the first radiating element portion and the first parasitic element portion flow in a direction opposite to each other so that an electric field is formed in the horizontal direction. Built-in RFID antenna used in the terminal. The method of claim 1, wherein the first radiating element unit Built-in RFID antenna used in a mobile communication terminal, characterized in that the monopole type. A ground portion that is grounded; A first feed part and a first short circuit part which are vertically connected to an edge portion of one side end of the ground part are formed, and a first radiation pattern of a meander line shape is formed to extend with the first feed part and the first short part; A first radiation element portion formed by a second radiation pattern extending downwardly perpendicularly to the first radiation pattern; And A second radiation pattern which is vertically connected to the other side edge portion of the ground portion connected to the first feed portion and the first short circuit portion and a third radiation pattern symmetrically formed with the first radiation pattern to extend to the second short circuit portion. And a first parasitic element portion formed with a fourth radiation pattern formed to be symmetrical with the second radiation pattern so as to extend from the third radiation pattern. The method according to claim 4, The current of the ground portion flows toward the first radiating element portion and the first parasitic element portion, and the first radiating element portion and the first parasitic element portion flows in the same direction so that the electric field is formed in the horizontal direction. Built-in RFID antenna used for. A ground portion that is grounded; A first feed part and a first short circuit part which are vertically connected to a central portion of one end of the ground part are formed, and a first radiation pattern of a meander line type is formed to extend with the first feed part and the first short part; A first radiation element portion formed by a second radiation pattern extending downwardly perpendicularly to the first radiation pattern; And The first short circuit portion and the first short circuit portion connected to the first and the second short circuit portion and the second short circuit portion which is vertically connected to the center portion spaced apart from the first feed portion at a distance from the first short portion connected to the first short circuit portion; And a first parasitic element portion formed with a fourth radiation pattern formed symmetrically with the second radiation pattern so as to form a third radiation pattern symmetrically with the radiation pattern. Built-in RFID antenna used. The method according to claim 5, The current of the ground portion flows toward the first radiating element portion and the first parasitic element portion, and the first radiating element portion and the first parasitic element portion flows in the same direction so that the electric field is formed in the horizontal direction. Built-in RFID antenna used for.

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