KR100705359B1 - Balance antenna and tag mountable on metallic plates - Google Patents

Abstract

According to the present invention, a radiation patch formed on a PCB substrate, a loop feed line formed on one side of the radiation patch, a first slit line formed inside the loop feed line, and formed on the outside according to the shape of the loop feed line And a third slit line connected to a second slit line from a center of the side surface of the radiation patch facing the second slit line and the loop-type feed line.

Therefore, in the present invention, since the radiation patch is electrically open with the feed line, it is easier to be conjugated with the microchip compared to the direct feed, and the current is fed in reverse phase to each other in the two regions of the radiation patch through the loop feed line. The change in the characteristics of the antenna with respect to the size of the metal attached to the ground substrate is reduced, there is an effect that can be used by attaching the antenna anywhere made of metal or non-metal.

Induction, Loop, Resonance, Phase, Conjugate Matching, Coupling, Bandwidth, Radiation Pattern

Description

 Balance Antenna and Tag Mountable on Metallic Plates

1 is a balance antenna attachable to a metal according to an embodiment of the present invention

2 is a balance tag attachable to a metal according to an embodiment of the present invention

3 is a balance tag attachable to a metal according to another embodiment of the present invention

4 is a current flow diagram of the radiation patch and the feed line according to Figure 2 of the present invention

5 is a graph showing the measured bandwidth according to FIG. 2 of the present invention.

6 is a graph showing a radiation pattern according to the size change of the metal according to FIG. 2 of the present invention

* Description of the main drawing codes *

100: PCB substrate 200: radiation patch

300: loop type feed line 400: first slit line

410: second slit line 420: third slit line

430: fourth slit line 500: short circuit

600: grounding board 700: microchip

The present invention relates to a balance antenna and a tag attachable to a metal, and more particularly, to a balance antenna and a tag attachable to a metal in which the performance change of the antenna with respect to the characteristics and positions of the ground substrate and the attached object is reduced.

As a technology related to an inverted-F antenna having a slot formed in a radiating plate to which a conventional electromagnetic coupling feeding method is applied, Application No. 10-2003-0099743 is provided to be spaced apart in an upper direction of a PCB substrate and has an electromagnetic coupling. It provides an inverted-F type antenna having a slot formed in the radiating plate to which the electromagnetic coupling feeding method is applied to form a slot having various shapes in the radiating plate fed by the feeding method to reduce the size of the antenna more efficiently. Another purpose is to form a slit having a predetermined length and width so that the resonance frequency can be tuned to a predetermined portion that does not intersect the slot formed in the radiating plate so that the resonance frequency in the high frequency band can be precisely adjusted. An inverted-F antenna with a slot on the radiating plate to which the ring feeding is applied is perpendicular to the PCB board and the feeding point of the PCB board. The radiating plate vertically formed from the feeding line and the short circuit point formed is installed at a predetermined interval, and the dielectric is filled to provide an electromagnetic gap between the PCB board and the feeding line and between the feeding line and the radiating plate, respectively. In the inverted-F type antenna for supplying energy from the power supply line to the radiator by an electromagnetic coupling method, the radiation plate to be provided at a predetermined distance in the upper direction of the power supply line in accordance with the shape of the antenna Characterized in that the slot having a predetermined length and width is provided to improve the surface current density of the, the radiating plate had a technique that is further provided with a tuning slit for adjusting the resonant frequency in addition to the slot.

However, the conventional technique has a structure in which the radiation patch has a positive charge and the ground substrate has a negative charge, and the direction of the electric field always faces the ground substrate and the radiation patch, and the change of current caused by the ground substrate is prevented. By changing the electrical characteristics of the overall antenna, there was a problem in reducing the performance of the antenna according to the change of the ground substrate and position.

Therefore, the present invention has been made to solve the above problems, an object of the present invention is because the ground patch is electrically open with the feed line, the loop feed line is fed to the two regions of the radiation patch in the reverse phase of the ground substrate It is an object of the present invention to provide a balance antenna and a tag that can be attached to a metal to reduce the performance change of the antenna with respect to the characteristics and position of the object to be attached.

In order to achieve the above object, according to an embodiment of the present invention, a radiation patch formed on a PCB substrate, a loop feed line formed on one side of the radiation patch, and a first slit line formed inside the loop feed line and the loop feed According to the shape of the line is characterized in that the second slit line formed on the outside and the third slit line connected to the second slit line from the center of the radiation patch side facing the loop feed line.

According to an embodiment of the present invention, a short circuit part is coupled to both ends of the side surface of the radiation patch and extends to face the loop feed line, and further includes a short circuit portion for adjusting the size of the radiation patch.

According to an embodiment of the present invention, the ground board is vertically connected to the short circuit part and spaced apart at regular intervals in parallel with the PCB substrate.

According to an embodiment of the present invention, the fourth slit line is further connected to the third slit line to adjust the resonance length of the radiation patch.

According to an embodiment of the present invention, the radiation patch is divided into two regions by a third slit line, and the two regions of the radiation patch are fed to each other in reverse phase through a loop feed line.

According to one embodiment of the invention the radiation patch is formed in the shape of a square, oval and polygon, the shape of the loop-type feed line according to the shape of the radiation patch is characterized in that the shape of the rectangle, oval and polygon do.

According to an embodiment of the present invention, the loop type feed line is characterized in that the feed by the inductively coupled feed method using a feed loop.

According to another embodiment of the present invention according to the shape of the radiation patch formed on the PCB substrate and the loop feed line formed on one side of the radiation patch and the first slit line formed inside the loop feed line and the loop feed line And a microchip formed at a lower center of the third slit line connected to the second slit line and a second slit line formed from an outer side of the radial patch side surface facing the second slit line and the loop feed line. .

According to another embodiment of the present invention is further characterized in that it is further provided with a short circuit portion coupled to both ends of the side and the extended side of the radiation patch facing the loop feed line to control the size of the radiation patch.

According to another embodiment of the present invention is further characterized in that it is further provided with a ground substrate which is vertically connected to the short circuit portion and spaced apart at regular intervals in parallel with the PCB substrate.

According to another embodiment of the present invention is further characterized in that the fourth slit line is connected to the third slit line for adjusting the resonance length of the radiation patch.

According to another embodiment of the present invention, the radiation patch is divided into two regions by a third slit line, and the two regions of the radiation patch are fed to each other in reverse phase through a loop-type feed line.

According to another embodiment of the present invention, the radiation patch is formed in the shape of a rectangle, oval and polygon, and the shape of the loop feed line is also modified in the form of a rectangle, oval and polygon according to the shape of the radiation patch. It is done.

According to another embodiment of the present invention, the loop type feed line is characterized by feeding in a feed-inductive feeding method using a feed loop.

According to another embodiment of the present invention, the microchip stores unique data, and the stored data is radiated at an opening point of the radiation patch.

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

1 is a configuration diagram of a balance antenna attachable to a metal according to the present invention, wherein the antenna includes a radiation patch 200 formed on a PCB substrate 100 and a loop feed line formed on one side of the radiation patch 200 ( 300, the first slit line 400 formed inside the loop feed line 300, the second slit line 410 formed outside in accordance with the shape of the loop feed line 300, and the loop. The third slit line 420 connected to the second slit line 410 from the center of the side of the radiation patch 200 facing the type feed line 300, and the radiation patch facing the loop feed line 300 Short circuit portion 500 coupled to both sides of the side and the extended side of the (200) and a vertical connection to the short circuit portion 500 and the ground substrate 600 spaced at regular intervals in parallel with the PCB substrate 100 Is done.

In more detail, the radiation patch 200 is divided into two regions by the third slit line 420, and the two divided regions have a resonance length of λ / 4 and are fed in reverse phase to each other, thereby making it one of two regions. As soon as the region of has a positive charge, the other region has a negative charge.

In addition, the radiation patch 200 is electrically open with the loop-type feed line 300 has a characteristic that can be easily conjugated with the microchip 700.

In particular, the radiation patch 200 is an area in which the flow of current is minimal in the two areas, and becomes an open point at which an electric field is radiated.

The PCB substrate 100 is a dielectric substrate composed of the radiation patch 200 and the loop feed line 300, the dielectric substrate is preferably made of a 46mm x 54mm area and a thickness of 0.6mm.

The loop type feed line 300 feeds two regions of the radiation patch 200 in reverse phase to each other using a feed loop, and uses an inductively coupled feed method to facilitate conjugation matching.

In addition, the loop feed line 300 feeds two regions of the radiation patch 200 in reverse phase to each other so that one region has a positive charge and the other region has a negative charge, thereby grounding. Has the effect of reducing the amount of current induced into the substrate, Performance change of the antenna with respect to the characteristics and position of the object to be attached to the ground substrate 600 is reduced.

The first slit line 400 is positioned inside the loop feed line 300 with a general thickness that prevents coupling of current and radiation from the loop feed line 300.

The second slit line 410 has a general thickness that prevents coupling between current and radiated electromagnetic waves in the loop feed line 300 and the radiation patch 200, and is outside the loop feed line 300. Located in

The third slit line 420 has a general thickness in which coupling currents and radiated electromagnetic waves of two regions of the radiation patch 200 are formed and face the loop-type feed line 300. It is connected to the second slit line 410 from the center of one side of the 100.

The short circuit part 500 is formed perpendicular to both sides of the radiation patch 200 farthest from where the loop type feed line 300 is formed, and the radiation patch 200 is fed in reverse phase to each other. As soon as one of the regions has a positive charge, the other region has a negative charge, thereby reducing the amount of current induced to the ground substrate 600 and reducing the amount of current induced in the ground substrate 600. The performance change of the antenna is small.

In addition, the short circuit 500 has a characteristic of adjusting the size of the radiation patch 200.

The ground substrate 600 is vertically connected to the short circuit part 500, and is spaced at a predetermined interval in parallel with the PCB substrate 100, and an air dielectric exists in a space spaced at the predetermined interval.

In particular, the shape of the radiation patch 200 may be modified in the form of a square, oval, polygonal, etc., the shape of the loop-type feed line 300 is also rectangular, oval, polygonal according to the shape of the radiation patch 200. It is transformed into the shape of the back.

2 is a block diagram of a balance tag attachable to a metal according to an embodiment of the present invention, wherein the tag is attachable to a metal further comprising a microchip 700 located in the loop-type feed line 300 of FIG. 1. It is a block diagram of a balance tag.

In more detail, the microchip 700 stores unique data, and the stored data is radiated at an open point of the radiation patch 200.

3 is a balance tag attachable to a metal according to another embodiment of the present invention, the fourth slit line 430 connected to the third slit line 420 may be formed in a vertical, horizontal, polygonal, or the like form. The fourth slit line 430 adjusts the resonance length of the radiation patch 200.

4 is a flow chart of a radiation patch and a loop feed line according to FIG. 2 of the present invention, in which current is inductively coupled to the radiation patch 200 in two areas through the loop feed line 300, and the radiation patch Since the current directions of the two regions of 200 are opposite to each other, the direction of the electric field is formed left / right.

In particular, the electric field maximum point of the radiation patch 200 is the first area and the second area which is the minimum point of the current, and the radiation point which opens the electric field of the radiation patch 200.

5 is a graph showing the measured bandwidth according to FIG. 2 of the present invention, where the bandwidth measurement data is 3 dB and the change in power bandwidth is 13 [MHz] to 14 [MHz], indicating a change of only 1 [MHz]. In addition, the change of the resonance frequency also showed only the change of 1 [MHz].

It also operates within 902 [MHz]-928 [MHz] for changes in metal surface size.

6 is a graph showing a radiation pattern according to the change in the size of the metal according to FIG. 2 of the present invention, each radiation pattern is measured for the antenna attached to the free space and the metal, as in the case of a general antenna As the size of the plane increases, the reverse radiation of the antenna decreases, but the balance antenna and the tag attachable to the metal have little change in characteristics even if the size of the attached metal changes, unlike the conventional antenna.

Although the present invention has been described in detail so far, the embodiments mentioned in the process are only illustrative and are not intended to be limiting, and the present invention is provided by the following claims. Within the scope of not departing from the scope of the present invention, changes in the components that can be coped evenly will fall within the scope of the present invention.

As described above, in the present invention, the radiation patch is electrically opened with the feeding line, so that the microchip and the conjugate matching are easy. The loop feed line feeds the two regions of the radiation patch in reverse phase to each other, thereby reducing the amount of current induced by the radiation patch to the ground substrate. There is an effect of reducing the performance change of the antenna with respect to the characteristics and position of the ground substrate and the attached object.

Claims (15)

A radiation patch formed on the PCB substrate; A loop feed line formed on one side of the radiation patch; A first slit line formed inside the loop feed line; A second slit line formed on the outside according to the shape of the loop feed line; And And a third slit line connected to a second slit line from the center of the radiation patch side surface facing the loop feed line. The balance antenna attachable to the metal of claim 1, further comprising a short circuit portion coupled to both ends of the radiation patch facing the loop feed line and extending from both ends thereof to adjust the size of the radiation patch. . 3. The balance antenna of claim 2, further comprising a ground board connected to the short circuit and vertically spaced apart from each other in parallel with the PCB substrate. 4. The balance antenna of claim 1, further comprising a fourth slit line connected to the third slit line to adjust a resonance length of the radiation patch. 5. 5. The balance as claimed in claim 4, wherein the radiation patch is divided into two regions by a third slit line, and the two regions of the radiation patch are fed out of phase with each other through a loop feed line. antenna. The radiation patch according to any one of claims 1 to 3, wherein the radiation patch is formed in the shape of a rectangle, an oval, and a polygon, and according to the shape of the radiation patch, the shape of the loop feed line is also in the shape of the rectangle, the oval, and the polygon. Balanced antenna attachable to the metal, characterized in that the deformation. The balance antenna as claimed in any one of claims 1 to 3, wherein the loop type feed line feeds by an inductively coupled feed method using a feed loop. A radiation patch formed on the PCB substrate; A loop feed line formed on one side of the radiation patch; A first slit line formed inside the loop feed line; A second slit line formed on the outside according to the shape of the loop feed line; A third slit line connected to a second slit line from the center of the radiation patch side facing the loop feed line; And Balance tag attachable to metal, characterized in that the microchip is formed in the lower center of the loop-type feed line. 10. The balance tag of claim 8, further comprising a short circuit portion coupled to both ends of the radiation patch facing the loop feed line and extending from both ends thereof to adjust the size of the radiation patch. . 10. The balance tag of claim 9, further comprising a ground board connected vertically to the short circuit and spaced apart at regular intervals in parallel with the PCB substrate. The balance tag according to any one of claims 8 to 10, further comprising a fourth slit line connected to the third slit line to adjust a resonance length of the radiation patch. 12. The balance as claimed in claim 11, wherein the radiation patch is divided into two regions by a third slit line, and the two regions of the radiation patch are fed out of phase with each other through a loop feed line. tag. The radiation patch according to any one of claims 8 to 10, wherein the radiation patch is formed in the shape of a rectangle, an ellipse, and a polygon, and the shape of the loop feed line is also in the shape of the rectangle, the oval, and the polygon according to the shape of the radiation patch. Balance tag attachable to the metal, characterized in that the deformation. The balance tag according to any one of claims 8 to 10, wherein the loop type feed line feeds in an inductively coupled feed method using a feed loop. The balance tag of claim 8, wherein the microchip stores unique data, and the stored data is radiated at an open point of the radiation patch.

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