KR102564795B1 - Combo antenna module - Google Patents

Abstract

The present invention relates to a combo antenna module, which is formed in a printed circuit board, a loop shape having a plurality of turns, and a first radiation pattern for wireless power transmission formed on a first surface of the printed circuit board, and a loop shape having a plurality of turns. It is formed and connected to the first radiation pattern for wireless power transmission, and includes a second radiation pattern for wireless power transmission formed on the second surface of the printed circuit board and a radiation pattern for electronic payment formed on the second surface of the printed circuit board. , Part of the second radiation pattern for wireless power transmission is formed narrower than the line width of the first radiation pattern for wireless power transmission, and the radiation pattern for electronic payment is wound along the spaced apart space between the second radiation patterns for wireless power transmission.

Description

Combo antenna module {COMBO ANTENNA MODULE}

The present invention relates to a combo antenna module mounted on an electronic device, and more particularly, to a combo antenna module including a plurality of antennas resonating in different frequency bands.

Along with the development of technology, portable terminals such as mobile phones, PDAs, PMPs, navigations, and laptops provide DMB, wireless Internet, and short-distance communication between devices in addition to basic functions such as calls, video/music playback, and navigation. Additional features are provided. Accordingly, the portable terminal includes a plurality of antennas for wireless communication such as wireless Internet and Bluetooth.

In addition, there is a trend in recent years to apply functions such as information exchange between terminals, payment, ticket reservation, and search to portable terminals using short-range communication (ie, NFC). To this end, the portable terminal is equipped with an antenna module (ie, NFC antenna module) used for short-range communication. At this time, the NFC antenna module used is one of the electronic tags (RFID) and transmits data between terminals at a short distance of about 10 cm as a non-contact short-range wireless communication module using a frequency band of about 13.56 MHz. NFC is widely used not only for payment, but also for transmission of product information or travel information for visitors in supermarkets or general stores, transportation, and access control locks.

In addition, recently, as functions related to electronic payments using mobile terminals, such as Apple Pay and Samsung Pay, are required, antennas for electronic payments are mounted on mobile terminals. For example, since Samsung Pay performs electronic payment using a magnetic secure transmission method, a magnetic secure transmission (MST) antenna is mounted in a mobile terminal supporting Samsung Pay.

On the other hand, as miniaturization and thinning are required in the market for portable terminals, the mounting space is gradually decreasing. Accordingly, portable terminal manufacturers are applying a combo antenna module in which a plurality of antennas are integrated into one portable terminal.

Along with this, portable terminal manufacturers are developing various combo antenna modules to reduce the unit cost of various parts as unit price competition intensifies in the portable terminal market. For example, the combo antenna module is composed of various composite materials such as FPCB, shielding sheet, heat dissipation sheet, etc., and various studies are being conducted to reduce the unit cost of the portable terminal through size reduction of the material.

Korean Patent Registration No. 10-0505847 (Title: Removable battery cover with loop antenna and mobile phone for non-contact wireless payment using it)

The present invention has been proposed in view of the above circumstances, and an object of the present invention is to provide a combo antenna module that prevents an increase in unit cost of the combo antenna module by minimizing the size of a flexible printed circuit board while maintaining antenna performance.

In order to achieve the above object, a combo antenna module according to an embodiment of the present invention is formed in a loop shape having a printed circuit board and a plurality of turns, and a first radiation pattern for wireless power transmission formed on a first surface of the printed circuit board. , formed in a loop shape having a plurality of turns, connected to the first radiation pattern for wireless power transmission, and formed on the second surface of the printed circuit board and the second radiation pattern for wireless power transmission formed on the second surface of the printed circuit board It includes a radiation pattern for electronic payment, a part of the second radiation pattern for wireless power transmission is formed narrower than a line width of the first radiation pattern for wireless power transmission, and the radiation pattern for electronic payment is between the second radiation patterns for wireless power transmission. It winds along the separation space of

In the second radiation pattern for wireless power transmission, the line width of some of the turns is narrower than the line width of the first radiation pattern for wireless power transmission overlapped with the printed circuit board interposed therebetween, and the line width of the outermost turn and the innermost The line widths of the plurality of turns adjacent to the outermost turn may be narrower than the line width of the first radiation pattern for wireless power transmission.

The sum of the line width of the second radiation pattern for wireless power transmission, the line width of the radiation pattern for electronic payment, and the separation width between the second radiation pattern for wireless power transmission and the radiation pattern for electronic payment is the line width of the first radiation pattern for wireless power transmission. may be below.

Among the second radiation patterns for wireless power transmission, the radiation pattern for electronic payment may be wound along a spaced space between adjacent turns having a narrow line width.

The second radiation pattern for wireless power transmission and the radiation pattern for electronic payment may be wound in the same direction along the same winding axis. The number of turns of the radiation pattern for electronic payment may be less than the number of turns of the second radiation pattern for wireless power transmission.

A part of the radiation pattern for electronic payment winds along the spacing between the radiation patterns for second wireless power transmission, and the rest of the radiation pattern for electronic payment passes through the radiation pattern for second wireless power transmission. The external space of the radiation pattern may be wound, and the second radiation pattern for wireless power transmission may have one or more penetrating paths through which the radiation pattern for electronic payment passes.

The combo antenna module according to an embodiment of the present invention may further include a radiation pattern for short-range communication that is wound along an outer circumference of the second radiation pattern for wireless power transmission.

A part of the electronic payment radiation pattern is wound along the space between the second radiation patterns for wireless power transmission, and the rest of the radiation pattern for electronic payment passes through the second radiation pattern for wireless power transmission and the radiation pattern for short-range communication. 2 The outer space of the radiation pattern for wireless power transmission can be wound. At this time, the second radiation pattern for wireless power transmission and the radiation pattern for short-range communication may form one or more through-paths through which the radiation pattern for electronic payment passes.

According to the present invention, the combo antenna module reduces the line width of some turns of the radiation pattern for wireless power transmission on one side, and the radiation pattern for electronic payment is wound through the spaced space between the radiation patterns for wireless power transmission with the line width. By doing so, there is an effect of minimizing the size of the flexible printed circuit board.

In addition, the combo antenna module reduces the line width of some of the turns of the radiation patterns for wireless power transmission on one side, and the radiation pattern for electronic payment is wound through the space between the radiation patterns for wireless power transmission with the line width. There is an effect of reducing the unit cost of the combo antenna module by minimizing the size of the flexible printed circuit board having the highest unit cost ratio among the materials constituting the antenna module.

In addition, the combo antenna module reduces the line width of some turns of the radiation pattern for wireless power transmission on one side, and the radiation pattern for electronic payment is wound through the space between the radiation patterns for wireless power transmission with the line width. The size of the flexible printed circuit board can be minimized without reducing the size of the radiation pattern for power transmission.

In addition, the combo antenna module minimizes the size of the flexible printed circuit board without reducing the size of the radiation pattern for wireless power transmission, thereby reducing the unit cost of the combo antenna module while maintaining the same level of wireless power transmission performance as the existing combo antenna module. There are effects that can be done.

In addition, the combo antenna module reduces the line width of some turns of the radiation pattern for wireless power transmission on one side, and the radiation pattern for electronic payment is wound through the spaced space between the radiation patterns for wireless power transmission with reduced line width, There is an effect of minimizing mutual signal interference (cancellation) by winding the same winding shaft in the same direction as the radiation pattern for wireless power transmission and the radiation pattern for electronic payment.

In addition, the combo antenna module reduces the line width of some turns of the radiation pattern for wireless power transmission on one side, and the radiation pattern for electronic payment is wound through the spaced space between the radiation patterns for wireless power transmission with reduced line width, There is an effect of improving the performance (recognition distance, recognition range) of the radiation pattern for electronic payment by increasing mutual inductance between the radiation pattern for wireless power transmission and the radiation pattern for electronic payment.

1 to 4 are views for explaining a combo antenna module according to a first embodiment of the present invention.
5 to 9 are views for explaining a combo antenna module according to a second embodiment of the present invention.
10 to 12 are views for explaining a combo antenna module according to a second embodiment of the present invention.

Hereinafter, the most preferred embodiments of the present invention will be described with reference to the accompanying drawings in order to explain in detail to the extent that those skilled in the art can easily practice the technical idea of the present invention. . First, in adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description will be omitted.

Referring to FIGS. 1 and 2 , the combo antenna module 100 according to the first embodiment of the present invention includes an antenna sheet 110 on which a plurality of radiation patterns are formed, and an adhesive bonded to the first surface of the antenna sheet 110. It is composed of a sheet 130, a resin sheet 150 adhered to the antenna sheet 110 through the adhesive sheet 130, and a magnetic sheet 170 disposed on the first surface of the antenna sheet 110. Here, as an example, the first surface of the antenna sheet 110 is a surface disposed in the direction of the main body (display) of the mobile terminal, and the second surface of the antenna sheet 110 is a surface disposed in the direction of the rear cover of the mobile terminal. .

3 and 4, the antenna sheet 110 includes a flexible printed circuit board 111, a radiation pattern 112 for wireless power transmission, a radiation pattern 113 for short-range communication, and a radiation pattern 114 for electronic payment. can be configured to include

Radiation patterns 112 for wireless power transmission are disposed on both sides of the flexible printed circuit board 111 . The radiation pattern 112 for wireless power transmission is composed of a loop pattern winding both sides of the flexible printed circuit board 111 . That is, the radiation pattern 112 for wireless power transmission is the loop-shaped first radiation pattern 112a for wireless power transmission disposed on the first surface of the flexible printed circuit board 111 and the first radiation pattern 112a of the flexible printed circuit board 111. It includes a loop-shaped second radiation pattern 112b for wireless power transmission disposed on two surfaces. At this time, the first and second radiation patterns 112b for wireless power transmission are connected through via holes. Here, as an example, the first surface of the flexible circuit board is a surface disposed in the direction of the main body (display) of the portable terminal, and the second surface of the flexible circuit board is a surface disposed in the direction of the rear cover of the portable terminal.

The radiation pattern 113 for short-range communication is disposed on one surface of the flexible printed circuit board 111 . The radiation pattern 113 for short-distance communication is composed of a loop pattern that is wound multiple times on one side of the flexible printed circuit board 111 . The radiation pattern 113 for short-range communication is disposed on the outer periphery of the radiation pattern 112 for wireless power transmission. For example, the radiation pattern 113 for short-range communication is disposed on the outer circumference of the second radiation pattern 112b for wireless power transmission disposed on the second surface.

The electronic payment radiation pattern 114 is disposed on at least one of both sides of the flexible printed circuit board 111 . The electronic payment radiation pattern 114 is composed of a loop pattern that is wound multiple times on one side of the flexible printed circuit board 111 . The radiation pattern 114 for electronic payment is disposed on the second surface of the loop-shaped first electronic payment radiation pattern 114 disposed on the first surface of the flexible printed circuit board 111 and the flexible printed circuit board 111 An example is to include a loop-shaped second radiation pattern 114 for electronic payment. At this time, the radiation pattern 114 for electronic payment is disposed above or below the radiation pattern 113 for short-distance communication in the drawing.

The antenna performance of the radiation pattern 114 for electronic payment increases as the inductance increases. When the size of the flexible printed circuit board 111 is increased to increase the inductance of the radiation pattern 114 for electronic payment, the unit price increases.

Accordingly, the combo antenna module 100 increases the inductor of the radiation pattern 114 for electronic payment by sharing the radiation pattern 114 for electronic payment and the radiation pattern 112 for wireless power transmission. That is, both ends of the radiation pattern 112 for wireless power transmission are connected to the first terminal and the second terminal, respectively, and both ends of the radiation pattern 114 for electronic payment are connected to the second terminal and the third terminal. Through this, the radiation pattern for electronic payment shares the radiation pattern 112 for wireless power transmission.

However, in the combo antenna module 100 according to the first embodiment of the present invention, since the radiation pattern 114 for electronic payment is disposed outside the radiation pattern 113 for short-distance communication on the drawing, the flexible printed circuit board 111 As the size increases, the cost of the combo antenna module 100 increases.

Accordingly, the second embodiment of the present invention proposes a combo antenna module having antenna performance equal to or better than that of the first embodiment while preventing an increase in unit price of the combo antenna module by minimizing the size of the flexible printed circuit board.

5 and 6, the combo antenna module 200 according to the second embodiment of the present invention includes an antenna sheet 210 on which a plurality of radiation patterns are formed, and a second surface of the antenna sheet 210 adhered to the antenna sheet 210. 1 adhesive sheet 220, a first resin sheet 230 adhered to the antenna sheet 210 through the first adhesive sheet 220, and a second adhesive sheet 240 adhered to the second surface of the antenna sheet 210. ), the second resin sheet 250 adhered to the antenna sheet 210 through the second adhesive sheet 240, and the magnetic sheet 260 disposed on the second surface of the antenna sheet 210.

7 and 8, the antenna sheet 210 includes a flexible printed circuit board 211, a radiation pattern 212 for wireless power transmission, a radiation pattern 213 for short-range communication, and a radiation pattern 214 for electronic payment. can be configured to include

Radiation patterns 212 for wireless power transmission are disposed on both sides of the flexible printed circuit board 211 . The radiation pattern 212 for wireless power transmission is composed of a loop pattern winding both sides of the flexible printed circuit board 211 . That is, the radiation pattern 212 for wireless power transmission is the loop-shaped first radiation pattern 212a for wireless power transmission disposed on the first surface of the flexible printed circuit board 211 and the first radiation pattern 212a of the flexible printed circuit board 211. It includes a loop-shaped second radiation pattern 212b for wireless power transmission disposed on two surfaces. In this case, the first and second radiation patterns 212b for wireless power transmission are connected through via holes.

The radiation pattern 213 for short-distance communication is disposed on one surface of the flexible printed circuit board 211 . The radiation pattern 213 for short-distance communication is composed of a loop pattern that is wound multiple times on one surface of the flexible printed circuit board 211 . The radiation pattern 213 for short-range communication is disposed on the outer periphery of the radiation pattern 212 for wireless power transmission. For example, the radiation pattern 213 for short-range communication is disposed on the outer circumference of the second radiation pattern 212b for wireless power transmission disposed on the second surface.

The radiation pattern 214 for electronic payment is composed of a loop-shaped radiation pattern wound through the first and second surfaces of the flexible printed circuit board 211 . The electronic payment radiation pattern 214 is wound approximately 2 to 3 times along the second radiation pattern 212b for wireless power transmission formed on the second surface of the flexible printed circuit board 211 . The radiation pattern 214 for electronic payment is wound along approximately 2 to 3 turns from the outermost turn to the inside of the second radiation pattern 212b for wireless power transmission. At this time, the number of turns of the radiation pattern 214 for electronic payment is less than the number of turns of the second radiation pattern 212b for wireless power transmission.

The electronic payment radiation pattern 214 is disposed between two adjacent turns of the second radiation pattern 212b for wireless power transmission. At this time, when the second radiation pattern 212b for wireless power transmission maintains the same line width as the overlapping first radiation pattern 212a for wireless power transmission with the flexible printed circuit board 211 therebetween, the second wireless power transmission In order to secure a separation width (distance) between the radiation pattern 212b for electronic payment and the radiation pattern 214 for electronic payment, the size of the flexible printed circuit board 211 has no choice but to increase.

Accordingly, referring to FIG. 9 , a part of the second radiation pattern 212b for wireless power transmission has a narrower line width than the overlapping first radiation pattern 212a for wireless power transmission with the flexible printed circuit board 211 interposed therebetween. have The second radiation pattern 212b for wireless power transmission has a narrower line width than the first radiation pattern 212a for wireless power transmission in 2 to 3 turns from the outermost turn to the inside.

In this case, the line width of the second radiation pattern 212b for wireless power transmission, the line width of the radiation pattern 214 for electronic payment, and the separation width between the second radiation pattern 212b for wireless power transmission and the radiation pattern 214 for electronic payment. A value obtained by summing is equal to the line width of the first radiation pattern 212a for wireless power transmission. Here, the same line width may include not only exactly the same line width, but also a case having a difference within an error range.

For example, assuming that the line width of the first radiation pattern 212a for wireless power transmission is approximately 1 mm, the line width of the second radiation pattern 212b for wireless power transmission is approximately 0.7 at 2 to 32 turns from the outermost turn. mm, the line width of the electronic payment radiation pattern 214 is approximately 0.1 mm, and the separation width between the second radiation pattern 212b for wireless power transmission and the electronic payment radiation pattern 214 may be approximately 0.1 mm. there is.

As such, the combo antenna module 200 according to the second embodiment of the present invention reduces the line width of some turns of the radiation pattern 212 for wireless power transmission on one side, and the radiation pattern for wireless power transmission with the reduced line width ( 212), the radiation pattern for electronic payment is wound through the spaced space between them. Accordingly, the size of the flexible printed circuit board 211 can be reduced compared to the combo antenna module 100 of the first embodiment in which the radiation pattern 214 for electronic payment is disposed above or below the radiation pattern 213 for short-range communication. .

In addition, the radiation pattern 214 for electronic payment shares a winding shaft with a radiation pattern for wireless power transmission, winds the winding shaft in the same direction as the radiation pattern for wireless power transmission, and turns a predetermined turn like a part of the radiation pattern for wireless power transmission. (Approximately 2-3 turns).

Accordingly, the combo antenna module 200 according to the second embodiment of the present invention maintains the recognition range and recognition distance of the radiation pattern 213 for short-range communication as it is, while maintaining the area where the radiation pattern 214 for electronic payment is formed (ie, , upper and lower portions of the radiation pattern 213 for short-distance communication) can be reduced, so that the size of the flexible printed circuit board 211 can be reduced compared to that of the flexible printed circuit board 111 of the first embodiment.

In addition, the combo antenna module 200 according to the second embodiment of the present invention can reduce the unit cost of the combo antenna module 200 by reducing the size of the flexible printed circuit board 211 .

In addition, the combo antenna module 200 according to the second embodiment of the present invention reduces the line width of some turns of the radiation pattern 212 for wireless power transmission, and the radiation pattern 212 for wireless power transmission with the reduced line width By winding the radiation pattern for electronic payment through the spaced space between them, interference from the surroundings by the radiation pattern 214 for electronic payment is reduced, and the recognition distance and recognition area of the radiation pattern 213 for short-range communication can be increased.

In addition, the combo antenna module 200 according to the second embodiment of the present invention reduces the radiation pattern as the size of the flexible printed circuit board 211 decreases, thereby concentrating the magnetic field to improve communication performance with the small tag. can improve

Through this, when the combo antenna module 100 of the first embodiment is composed of the flexible printed circuit board 211 having a size of about 107mmХ60mm, the combo antenna module 200 of the second embodiment has a size of about 63mmХ49mm. Antenna performance equal to or higher than that of the combo antenna module 100 of the first embodiment can be implemented.

However, the combo antenna module 200 according to the second embodiment of the present invention recognizes the radiation pattern 214 for electronic payment because the radiation pattern 214 for electronic payment is concentrated in the center of the flexible printed circuit board 211. range may be reduced.

10 to 12, in the combo antenna module 200 according to the second embodiment of the present invention, a part (approximately 3/4 turn) of the radiation pattern 214 for electronic payment disposed on the second surface is It is wound along the radiation pattern 212 for wireless power transmission, and the remainder (approximately 1/4 turn) penetrates the radiation pattern 212 for wireless power transmission and the radiation pattern 213 for short-range communication, thereby forming a radiation pattern for short-range communication in the drawing. The lower part of (213) can also be wound. That is, the radiation pattern 214 for electronic payment is the space between the radiation pattern 212 for wireless power transmission, the space between the outer circumference of the radiation pattern 212 for wireless power transmission and the inner circumference of the radiation pattern 213 for short-range communication, and short distance It is wound along the space arranged on the outer periphery of the radiation pattern 213 for communication.

To this end, a through path through which the radiation pattern 214 for electronic payment passes is formed between the second radiation pattern 212b for wireless power transmission and the radiation pattern 213 for short-range communication. Here, as an example, the through path is a space in which a radiation pattern is not formed as the radiation pattern detours to the first surface of the flexible printed circuit board 211 .

The radiation pattern 212 for wireless power transmission includes a first through path 212c and a second through path 212d, and the radiation pattern 213 for short-distance communication has a third through path 213a and a fourth through path ( 213b) is formed as an example.

At this time, the radiation pattern 214 for electronic payment passes through the first through path 212c and the third through path 213a sequentially, advances to the lower part of the radiation pattern 213 for short distance communication in the drawing, and passes through the fourth through path. 213b and the third penetration path 213a are sequentially passed through to enter the radiation pattern 212 for wireless power transmission.

Of course, the radiation pattern 214 for electronic payment passes through the second through path 212d and the fourth through path 213b sequentially, advances to the lower part of the radiation pattern 213 for short-range communication in the drawing, and passes through the third through path. 213a and the first through path 212c may be sequentially passed through to enter the radiation pattern 212 for wireless power transmission.

As such, in the combo antenna module 200 according to the second embodiment of the present invention, the radiation pattern 214 for electronic payment is separated from the radiation pattern 212 for wireless power transmission and the radiation pattern 213 for short-distance communication in the drawing. By forming a loop over the outside, it is possible to minimize the size of the flexible printed circuit board 211 while maintaining the recognition range of the radiation pattern 214 for electronic payment at the same level as the combo antenna module 100 of the first embodiment. .

Although the preferred embodiments according to the present invention have been described above, modifications can be made in various forms, and those skilled in the art can make various modifications and modifications without departing from the scope of the claims of the present invention. It is understood that this can be done.

100, 200: Combo antenna module
110, 210: antenna sheet
111, 211: flexible printed circuit board
112, 212: radiation pattern for wireless power transmission
112a, 212a: Radiation pattern for first wireless power transmission
112b, 212b: radiation pattern for second wireless power transmission
113, 213: radiation pattern for short-range communication
114, 214: radiation pattern for electronic payment
130: adhesive sheet 150: resin sheet
170, 260: magnetic sheet 220: first adhesive sheet
230: first resin sheet 240: second adhesive sheet
250: second resin sheet

Claims (12)

printed circuit board;
a first radiation pattern for wireless power transmission formed in a loop shape having a plurality of turns and formed on a first surface of the printed circuit board;
a second radiation pattern for wireless power transmission formed in a loop shape having a plurality of turns, connected to the first radiation pattern for wireless power transmission, and formed on a second surface of the printed circuit board; and
A radiation pattern for electronic payment formed on the second surface of the printed circuit board;
A part of the second radiation pattern for wireless power transmission is narrower than the line width of the first radiation pattern for wireless power transmission, and the radiation pattern for electronic payment is adjacent among a plurality of turns of the second radiation pattern for wireless power transmission. A combo antenna module that winds along the spacing between the two turns. According to claim 1,
The second radiation pattern for wireless power transmission has a line width of some of the plurality of turns formed narrower than the line width of the first radiation pattern for wireless power transmission overlapped with the printed circuit board interposed therebetween. According to claim 2,
The second radiation pattern for wireless power transmission is a combo antenna module in which a line width of an outermost turn and a line width of a plurality of turns adjacent to the outermost turn are narrower than a line width of the first radiation pattern for wireless power transmission. . According to claim 1,
The sum of the line width of the second radiation pattern for wireless power transmission and the line width of the radiation pattern for electronic payment and the separation width between the second radiation pattern for wireless power transmission and the radiation pattern for electronic payment is the first wireless power transmission Combo antenna module that is less than or equal to the line width of the radiation pattern. According to claim 1,
The radiation pattern for electronic payment is wound along the spaced space between adjacent turns having a narrow line width among the second radiation patterns for wireless power transmission. According to claim 1,
The second radiation pattern for wireless power transmission and the radiation pattern for electronic payment are wound in the same direction along the same winding axis. According to claim 1,
The number of turns of the radiation pattern for electronic payment is less than the number of turns of the second radiation pattern for wireless power transmission. According to claim 1,
A portion of the radiation pattern for electronic payment is wound along a spaced apart space between the second radiation patterns for wireless power transmission,
The remainder of the electronic payment radiation pattern passes through the second radiation pattern for wireless power transmission and winds the outer space of the second radiation pattern for wireless power transmission. According to claim 8,
The second radiation pattern for wireless power transmission is a combo antenna module having one or more penetration paths through which the radiation pattern for electronic payment passes. According to claim 1,
The combo antenna module further comprising a radiation pattern for short-range communication winding along an outer circumference of the second radiation pattern for wireless power transmission. According to claim 10,
A portion of the electronic payment radiation pattern is wound along the spaced apart space between the second radiation patterns for wireless power transmission,
The remainder of the electronic payment radiation pattern passes through the second radiation pattern for wireless power transmission and the radiation pattern for short-range communication and winds the outer space of the second radiation pattern for wireless power transmission. According to claim 11,
The second radiation pattern for wireless power transmission and the radiation pattern for short-range communication are formed with one or more through-paths through which the radiation pattern for electronic payment passes.