KR101289662B1 - Mathod for optimum coupling of contactless comunication antenna and dual-resonance booster coil - Google Patents

Abstract

The present invention relates to an optimal coupling method of a non-contact communication antenna and a dual resonance booster coil. The present invention relates to an optimal coupling method of an antenna for contactless communication and a booster coil for dual resonance, which achieves excellent performance by coupling.
The object of the present invention is a coupling method of a non-contact communication antenna and a dual resonance booster coil, comprising: a main antenna coil inserted into a recess formed in a terminal and a booster coil seated on a terminal cover for protecting the inside of the terminal; However, one end of the booster coil is achieved by the optimal coupling method of the antenna for contactless communication and the booster coil for dual resonance, characterized in that arranged in contact with the end of the main antenna coil.

Description

Optimum Coupling Method of Non-contact Communication Antenna and Dual Resonance Booster Coils {Mathod for optimum coupling of contactless comunication antenna and dual-resonance booster coil}

The present invention relates to an optimal coupling method of a non-contact communication antenna and a dual resonance booster coil. The present invention relates to an optimal coupling method of an antenna for contactless communication and a booster coil for dual resonance, which achieves excellent performance by coupling.

When an antenna for contactless communication is mounted inside a terminal with a system to read or write an RF signal, the antenna should be designed to be very small when the implementation space is small. Thus, the radiation performance is also lowered, there was a problem that smooth RF communication is difficult. In addition, since the antenna is mounted inside the terminal, the antenna is subjected to radio interference from surrounding metallic materials, thereby increasing its difficulty.

In order to solve this problem, the booster coil is coupled with the main antenna to improve the radio performance by receiving the signal of the main antenna from the booster coil, and a method of increasing the bandwidth through double resonance has been devised.

In general, the main antenna and the booster coil is advantageously located in the center of the booster coil 210 in order to cause coupling throughout the pattern of the booster coil 210 as shown in FIG. However, when the physical size difference between the main antenna coil 110 and the booster coil 210 is large, even if the main antenna coil 110 is placed in the center of the booster coil 210 to induce coupling, due to the spatial difference in the coupling area. There was a problem that the performance is not improved at all because the coupling is not made smoothly due to the limitation in the radioactivity.

The present invention devised to solve the problems of the prior art as described above, even when the physical size difference between the main antenna and the booster coil is large, the optimum couple to conduct a smooth contactless communication even in a small terminal by inducing a smooth coupling with excellent radiation performance The purpose is to provide a ring structure.

The object of the present invention is a coupling method of a non-contact communication antenna and a dual resonance booster coil, comprising: a main antenna coil inserted into a recess formed in a terminal and a booster coil seated on a terminal cover for protecting the inside of the terminal; However, one end of the booster coil is achieved by the optimal coupling method of the antenna for contactless communication and the booster coil for dual resonance, characterized in that arranged in contact with the end of the main antenna coil.

Preferably, at least one of the main antenna coil or the booster coil is seated on an auxiliary substrate and is inserted into the groove or seated on the terminal cover.

Also preferably, the method may further include at least one of a first ferrite attached to the rear surface of the main antenna coil and a second ferrite attached to the rear surface of the booster coil.

Also preferably, the first ferrite is applied to the entire area of the main antenna coil, and the second ferrite is applied to the remaining portions except for the region where the coupling with the main antenna coil occurs.

The present invention devised to solve the problems of the prior art as described above, even when the physical size difference between the main antenna and the booster coil is large, the optimum couple to conduct a smooth contactless communication even in a small terminal by inducing a smooth coupling with excellent radiation performance There is an effect that can provide a ring structure.

1 is a view showing a coupling structure of a main antenna and a booster coil according to the prior art ((a) plan view, (b) front view),
2 is a view showing a coupling structure of a main antenna and a booster coil according to the present invention ((a) plan view, (b) front view),
Figure 3 is a view showing the difference in frequency inductance (Inductance) according to the prior art and the present invention,
4 is a detailed configuration diagram illustrating a coupling structure of a main antenna and a booster coil according to the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary terms and the inventor may appropriately define the concept of the term in order to best describe its invention It should be construed as meaning and concept consistent with the technical idea of the present invention.

Therefore, the embodiments described in this specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and do not represent all the technical ideas of the present invention. Therefore, It is to be understood that equivalents and modifications are possible.

Hereinafter, preferred embodiments of the present invention will be described in detail.

2 is a view showing a coupling structure of a main antenna and a booster coil according to the present invention ((a) plan view, (b) front view). As shown in Figure 2 (a) and 2 (b), the present invention in the coupling method of the antenna for contactless communication and the dual resonance booster coil, the main antenna coil is inserted into the groove formed inside the terminal 100 And a booster coil 210 seated on the terminal cover 200 for protecting the interior of the terminal 110 and the terminal 100, wherein one end of the booster coil 210 is in contact with an end of the main antenna coil 110. It is characterized by.

In this case, the main antenna receives a signal from the main antenna to improve radioactivity, and widens the bandwidth through double resonance to suppress communication failure.

In general, the main antenna coil 110 is positioned at the center of the booster coil 210 to induce coupling throughout the pattern, but when the physical size difference between the main antenna coil 110 and the booster coil 210 is large, The difference limits the radioactivity and prevents smooth coupling. Accordingly, in order to maximize the coupling effect between the main antenna coil 110 and the booster coil 210 as shown in FIG. 2 (b), the signal is transmitted through the end pattern of the booster coil 210 to the main antenna coil 110. It is arranged to be delivered.

3 is a view showing a difference in frequency inductance (frequency inductance) of the prior art and the present invention. Here, the prior art is to place the main antenna coil 110 in the center of the booster coil 210, the inductance is an important factor in determining the current transfer characteristics of the antenna in the antenna for contactless communication. In addition, the physical size difference between the main antenna coil 110 and the booster coil 210 in the drawing shown in Figure 3 is 1: 5 or more.

As shown in FIG. 3, when the same environment and the same antenna are applied, an inductance difference of 1 nH or more is shown for each frequency region. This is a very large value given that the typical inductance of a small antenna is 0.8 to 1.5 nH.

4 is a detailed configuration diagram illustrating a coupling structure of a main antenna and a booster coil according to the present invention. As shown in FIG. 4 in the general form factor of the terminal 100, at least one of the main antenna coil 110 or the booster coil 210 is seated on the first and second sub-boards 120 and 220 and inserted into the recess. It is preferable to be seated on the terminal cover 200.

At this time, any one or more of the main antenna coil 110 or the booster coil 210 is formed by embedding the coating coil on one surface of the first and second auxiliary substrates 120 and 220 or conductive on one surface of the auxiliary substrate. It can be formed by printing with ink.

Here, the coil of the coating coil is preferably composed of any one or more of Cu, Ag or Al.

In addition, it is preferable that the first and second ferrites 130 and 230 are applied to the rear surface of any one or more of the main antenna coil 110 or the booster coil 210, and the first and second ferrites ( 130 and 230 are attached to any one or more of the main antenna coil 110 or the booster coil 210 by an adhesive sheet.

In more detail, the first ferrite attached to the rear surface of the main antenna coil 110 is applied to the entire area of the main antenna coil 110, and the second ferrite attached to the rear surface of the booster coil 210 is the booster coil 210. It is preferable to apply the rest of the entire area except for the region of the pattern in which the coupling occurs in contact with the main antenna coil 110.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation, Various changes and modifications will be possible.

100: terminal 110: main antenna coil
120: first auxiliary substrate 130: first ferrite
200: terminal cover 210: booster coil
220: second auxiliary substrate 230: second ferrite

Claims (7)

In the coupling method of a non-contact communication antenna and a double resonance booster coil,
A main antenna coil inserted into a groove formed inside the terminal; And
Booster coil mounted on the terminal cover to protect the inside of the terminal
Including,
One end of the booster coil is disposed to contact the end of the main antenna coil, wherein at least one of the main antenna coil or the booster coil is seated on an auxiliary substrate and inserted into the groove or seated on the terminal cover. Optimal coupling method of a non-contact communication antenna and a double resonance booster coil.
delete The method of claim 1,
Any one or more of the main antenna coil or the booster coil is formed by embedding (embedding) with a covering coil on one surface of the auxiliary substrate.
The method of claim 3, wherein
The coil of the covering coil is an optimal coupling method of the antenna for contactless communication and the booster coil for dual resonance, characterized in that composed of any one or more of Cu, Ag or Al.
The method of claim 1,
Any one or more of the main antenna coil or the booster coil is formed by printing with conductive ink on one surface of the auxiliary substrate, the optimal coupling method of the antenna and the dual resonance booster coil for communication.
The method of claim 1,
Optimum coupling method of the non-contact communication antenna and the dual resonance booster coil further comprises any one or more of the first ferrite attached to the back of the main antenna coil or the second ferrite attached to the back of the booster coil. .

The method according to claim 6,
The first ferrite is applied to the entire area of the main antenna coil, and the second ferrite is applied to the remaining portion except for the region where the coupling with the main antenna coil occurs, the antenna for non-contact communication and the double resonance booster coil Optimal coupling method.

Images