KR20230172098A - Booster antenna for portable terminal - Google Patents

Abstract

We present a booster antenna for a mobile terminal that is made of a sheet or case attached to the rear of the mobile terminal and extends the recognition distance of short-range communication through a coupling effect with the NFC antenna built in the mobile terminal. The presented booster antenna for a mobile terminal includes a loop pattern, and as the booster antenna for a mobile terminal is placed on the rear of the mobile terminal, the loop pattern partially overlaps with the main NFC radiation pattern of the mobile terminal, thereby increasing the NFC recognition distance of the mobile terminal. .

Description

Booster antenna for mobile terminal {BOOSTER ANTENNA FOR PORTABLE TERMINAL}

The present invention relates to a booster antenna for a portable terminal installed on the rear of the portable terminal.

The vehicle is equipped with a smart key system. The smart key system provides the function of controlling door opening, door closing, ignition, etc. through simple key manipulation while the driver is in possession of a smart key (i.e. fob key, fob).

Vehicle manufacturers are applying various technologies (for example, Apple's CarKey) to vehicles to replace smart keys with smartphones equipped with a near-field communication (NFC) antenna. For example, the driver can open the car door by approaching the smartphone to the NFC reader installed on the car door, or start the car by placing the smartphone on a holder installed in the center fascia, glove box, etc.

For this purpose, a stand is mounted on the vehicle, and the stand is equipped with a wireless charging coil composed of a plurality of loop coils and an NFC antenna wound in a form surrounding the wireless charging coil. At this time, the size and location of the NFC antenna are determined based on the bar shape mainly used in smart phones.

However, since the NFC antenna mounted on a smartphone is designed to have a different mounting location and/or size for each model, an unrecognized area (Null) where NFC communication between the vehicle and the smartphone is not possible depending on the mounting location and/or size of the NFC antenna ) There is a problem that occurs.

Unrecognized areas can be resolved by changing the pattern design of the NFC antenna mounted on the holder. However, it is not easy to change the design of the NFC antenna pattern for vehicles that have already been released, and even if changed, it is impossible to design the NFC antenna pattern to reflect all various smartphones.

Unrecognized areas can also be resolved by standardizing the mounting location and size of the NFC antenna of the smartphone. However, since smartphones have different internal structures depending on the model and/or company, it is impossible to standardize the mounting location and size of the NFC antenna.

The matters described in the above background technology are intended to aid understanding of the background of the invention and may include matters that are not disclosed prior art.

Korean registered patent 10-2027347 Korean Patent Publication No. 10-2019-0054618 Korean registered patent 10-1667990

The present invention was proposed in consideration of the above circumstances and is manufactured as a sheet or case attached to the rear of a mobile terminal, expanding the recognition distance of short-distance communication through the coupling effect with the NFC antenna built into the mobile terminal. The purpose is to provide a booster antenna for a portable terminal.

In order to achieve the above object, the booster antenna for a portable terminal according to an embodiment of the present invention is disposed on the rear of the portable terminal, is formed on the base material and the base substrate, and the booster antenna for the portable terminal is disposed on the rear of the portable terminal. Accordingly, it includes a loop pattern configured to operate as an auxiliary radiator of the main NFC radiation pattern built into the mobile terminal, and the loop pattern overlaps at least a portion of the main NFC radiation pattern built into the mobile terminal.

The loop pattern may form one or more overlapping areas with the main NFC radiation pattern as the booster antenna for the mobile terminal is attached to the mobile terminal.

The loop pattern may be wound along an imaginary first winding axis orthogonal to the base substrate, and the first winding axis may be parallel to and spaced apart from the winding axis of the main NFC radiation pattern. Accordingly, the center of the loop pattern may be spaced apart from the center of the main NFC radiation pattern.

The loop pattern has an area that is different from the area of the main NFC radiation pattern, but the loop pattern may have an area that is smaller than the area of the main NFC radiation pattern.

The booster antenna for a mobile terminal according to an embodiment of the present invention may be disposed on a base material and connected to a loop pattern, and may further include a matching element that matches the resonance frequency and impedance between the main NFC radiation pattern and the loop pattern.

The loop pattern is disposed on the first side of the base substrate, and is a first radiation pattern in the shape of a loop wound along an imaginary first winding axis orthogonal to the base substrate, and is arranged to be spaced apart from the first radiation pattern on the first side of the base substrate. It may include a second radiation pattern and a third radiation pattern disposed on the second side of the base substrate and connecting the first radiation pattern and the second radiation pattern.

The first end of the first radiation pattern is connected to the first end of the matching element, the second end of the first radiation pattern is connected to the first end of the third radiation pattern through the first via hole, and the second radiation pattern is connected to the first end of the matching element. The first end may be connected to the second end of the matching element, and the second end of the second radiation pattern may be connected to the second end of the third radiation pattern through the second via hole.

The first winding axis is spaced apart from the winding axis of the main NFC radiation pattern, and the first radiation pattern may have an area smaller than that of the main NFC radiation pattern.

The booster antenna for a mobile terminal according to an embodiment of the present invention may further include an adhesive sheet disposed on the second side of the base substrate facing the rear of the mobile terminal or the inner surface of a case fitted into the rear of the mobile terminal. At this time, an adhesive is disposed on the first side of the adhesive sheet, and the first side of the adhesive sheet may be adhered to one of the rear surface of the portable terminal and the inner surface of the case.

The base material and the loop pattern may be molded into a case that is fitted on the rear of the mobile terminal and formed integrally with the case.

According to the present invention, the booster antenna for a mobile terminal is composed of a sheet attached to the rear of the mobile terminal or a case inserted into the mobile terminal, and the loop pattern of the booster antenna for the mobile terminal overlaps the main NFC radiation pattern of the mobile terminal to form the main NFC radiation pattern. It operates as an auxiliary radiator for the NFC radiation pattern. Accordingly, the booster antenna for a mobile terminal has the effect of expanding the recognition distance of the main NFC radiation pattern of the mobile terminal and minimizing the unrecognized area of the main NFC radiation pattern.

In addition, the booster antenna for a mobile terminal maintains near-field communication (NFC) performance between the holder and the mobile terminal at a constant level regardless of the size and/or mounting position of the main NFC radiation pattern mounted on the mobile terminal and the mounting position (direction) of the mobile terminal. It has the effect of maintaining the level or higher.

In addition, the booster antenna for a mobile terminal has the effect of allowing the mobile terminal to recognize the mobile terminal even if the alignment of the stand and the mobile terminal is misaligned, thereby allowing the mobile terminal to replace the fob of the vehicle.

1 is a diagram for explaining an example of a holder mounted on a vehicle.
FIG. 2 is a diagram illustrating an example of a portable terminal for replacing a pod of a vehicle.
Figure 3 is a diagram for explaining a booster antenna for a mobile terminal according to an embodiment of the present invention.
4 and 5 are diagrams for explaining the configuration of a booster antenna for a mobile terminal according to an embodiment of the present invention.
FIGS. 6 and 7 are diagrams for explaining a modified example of the first radiation pattern shown in FIG. 4.
Figure 8 is a diagram for explaining a booster antenna for a mobile terminal further including an adhesive sheet for attaching to the mobile terminal.
FIG. 9 is a diagram illustrating an example in which a booster antenna for a mobile terminal is disposed on the rear of a mobile terminal through adhesion according to an embodiment of the present invention.
FIG. 10 is a diagram illustrating an example in which the booster antenna for a mobile terminal according to an embodiment of the present invention is integrated with the case and is disposed on the rear of the mobile terminal.
FIG. 11 is a diagram illustrating an overlap structure between a loop pattern of a booster antenna for a mobile terminal and a main NFC radiation pattern of a mobile terminal according to an embodiment of the present invention.
FIG. 12 is a diagram for comparing and explaining a general mobile terminal and a mobile terminal with a booster antenna for a mobile terminal disposed on the rear according to an embodiment of the present invention.

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

The examples are provided to more completely explain the present invention to those skilled in the art, and the following examples may be modified in various other forms, and the scope of the present invention is limited to the following examples. It is not limited. Rather, these embodiments are provided to make the disclosure more faithful and complete and to fully convey the spirit of the invention.

The terms used herein are used to describe specific embodiments and are not intended to limit the invention. Additionally, in this specification, singular forms may include plural forms, unless the context clearly indicates otherwise. In the description of the embodiment, the top, bottom, left, and right directions are in principle based on the drawings.

The drawings are only intended to enable understanding of the spirit of the present invention, and should not be construed as limiting the scope of the present invention by the drawings. Additionally, in the drawings, relative thickness, length, or relative size may be exaggerated for convenience and clarity of explanation.

A stand on which a mobile terminal is mounted is installed in the vehicle. The holder can be installed in the vehicle's center fascia, glove box, etc. The holder performs short-distance communication with the portable terminal to enable wireless charging of the portable terminal and allow the driver to control the starting of the vehicle.

To this end, referring to FIG. 1, the vehicle holder 10 includes a wireless power transmission coil 12 for wireless charging of the mobile terminal 20, and an NFC radiation pattern for short-distance communication with the mobile terminal 20 ( 14) is built-in.

The wireless power transmission coil 12 is composed of a loop coil. The holder 10 may include a plurality of wireless power transmission coils 12, and the wireless power transmission coils 12 are arranged so that at least a portion of the wireless power transmission coils 12 overlap with other wireless power transmission coils 12.

The NFC radiation pattern 14 is composed of a conductor formed in a loop shape wound along the outer circumference of the area where the wireless power transmission coil 12 is disposed. At this time, the size and position of the NFC radiation pattern 14 are determined based on the bar shape mainly used in the portable terminal 20.

However, since the main NFC radiation pattern 24 mounted on the mobile terminal 20 is designed to have a different mounting position and/or size depending on the mobile terminal 20, the mobile terminal 20 is not recognized by the holder 10. There are cases where this is not possible.

Referring to FIG. 2, the wireless power receiving coil 22 is disposed at the center of the mobile terminal 20 based on the rear, and the main NFC radiation pattern 24 is disposed along the outer circumference of the wireless power receiving coil 22. do.

In some cases, the wireless power receiving coil 22 is disposed at the center (or bottom center) of the mobile terminal 20, and the main NFC radiation pattern 24 is disposed adjacent to the top.

If the main NFC radiation pattern (24) is manufactured to a sufficient size, short-distance communication with the holder (10) is possible regardless of the mounting position. However, if the size of the main NFC radiation pattern 24 is small or it is mounted in a specific location and the recognition range is not wide, short-distance communication becomes impossible or communication becomes impossible even if the alignment of the mobile terminal 20 with the holder 10 is slightly distorted. Performance becomes very low.

Accordingly, referring to FIG. 3, the booster antenna 100 for a mobile terminal according to an embodiment of the present invention is installed on the rear of the mobile terminal 20 or the case 30 (hereinafter referred to as case 30) for the mobile terminal 20. It is composed of an attached sheet, or is formed integrally with the case 30 and is placed on the rear of the portable terminal 20.

The booster antenna 100 for a mobile terminal includes a loop pattern 110 and is installed on the rear of the mobile terminal 20 so that the loop pattern 110 overlaps the main NFC radiation pattern 24 built into the mobile terminal 20. It is placed. At this time, the booster antenna 100 for a mobile terminal can expand the recognition distance (recognition range) of short-distance communication by the coupling effect in the area where the loop pattern 110 and the main NFC radiation pattern 24 overlap.

Accordingly, the booster antenna 100 for a mobile terminal is mounted on the holder 10 regardless of the size and/or mounting position of the main NFC radiation pattern 24 of the mobile terminal 20, the mounting position (direction) of the mobile terminal 20, etc. Allows the mobile terminal 20 to be recognized.

4 and 5, the booster antenna 100 for a mobile terminal according to the first embodiment of the present invention includes a base substrate 120, a first radiation pattern 130, a second radiation pattern 140, and a first radiation pattern 140. It is composed of three radiation patterns 150 and a matching element 160.

The base substrate 120 may be composed of a thin film substrate such as a film, sheet, or thin film substrate. The base substrate 120 may be a flexible printed circuit board (FPCB). For example, the base material 120 is a polypropylene (PP) sheet.

The first radiation pattern 130, the second radiation pattern 140, and the matching element 160 are disposed on the first surface (ie, top surface) of the base substrate 120. A third radiation pattern 150 is disposed on the second surface (ie, lower surface) of the base substrate 120.

The first radiation pattern 130 is disposed on the first side of the base substrate 120. The first radiation pattern 130 is formed in a loop shape with a predetermined number of turns. The first radiation pattern 130 is wound along a virtual first winding axis on the first surface of the base substrate 120 to form a first loop having a predetermined number of turns.

Here, in FIGS. 4 and 5, the first loop formed by the first radiation pattern 130 is shown as having 2 turns, but this is not limited to this, and as shown in FIGS. 6 and 7, the first radiation pattern The first loop formed by 130 may be formed to have three turns.

The first end of the first radiation pattern 130 is disposed in the outer area of the first loop and is connected to the first end of the matching element 160. The second end of the first radiation pattern 130 is disposed in the inner peripheral area of the first loop formed by the first radiation pattern 130. The second end of the first radiation pattern 130 is connected to the first end of the third radiation pattern 150 through one or more first via holes V1 penetrating the base substrate 120.

The second radiation pattern 140 is disposed on the first surface of the base substrate 120 and in the outer peripheral area of the first loop formed by the first radiation pattern 130.

The first end of the second radiation pattern 140 is connected to the second end of the matching element 160. The second end of the second radiation pattern 140 is connected to the second end of the first radiation pattern 130 through the third radiation pattern 150. The second end of the second radiation pattern 140 is connected to the second end of the third radiation pattern 150 through one or more second via holes V2 penetrating the base substrate 120.

The third radiation pattern 150 is disposed on the second side of the base substrate 120. The first end of the third radiation pattern 150 is connected to the second end of the first radiation pattern 130 through one or more first via holes V1. The second end of the third radiation pattern 150 is connected to the second end of the third radiation pattern 150 through one or more second via holes V2.

Through this, the first to third radiation patterns 130 to 150 wind the first and second sides of the base substrate 120 and form a loop pattern 110 having a predetermined number of turns. .

The loop pattern 110 operates as the sub-main NFC radiation pattern 24 through a coupling effect with the main NFC radiation pattern 24. To this end, the loop pattern 110 overlaps at least a portion of the main NFC radiation pattern 24 of the mobile terminal 20 as the booster antenna 100 for the mobile terminal is disposed on the rear of the mobile terminal 20.

The area of the loop pattern 110 is formed to be different from the area of the main NFC radiation pattern 24, but the area of the loop pattern 110 is formed to be smaller than the area of the main NFC radiation pattern 24.

If the area of the loop pattern 110 and the area of the main NFC radiation pattern 24 are formed to be the same or wide, the unrecognized area of the main NFC radiation pattern 24 is used by the booster antenna 100 for the mobile terminal to detect the area of the mobile terminal 20. Even if it is placed (attached) to the back of the , it remains as is. Accordingly, the area of the loop pattern 110 is formed to be smaller than the area of the main NFC radiation pattern 24.

Additionally, the center of the loop pattern 110 is spaced apart from the center of the main NFC radiation pattern 24. Here, as an example, the center is the winding axis of the loop formed by the loop pattern 110 and the main NFC radiation pattern 24.

Since the loop pattern 110 is formed with a smaller area than the main NFC radiation pattern 24, if the center of the loop pattern 110 is the same as the center of the main NFC radiation pattern 24, it overlaps the main NFC radiation pattern 24. Since this does not work, the coupling effect cannot be expected. Accordingly, the center of the loop pattern 110 is spaced apart from the center of the main NFC radiation pattern 24.

Matching element 160 is comprised of a capacitor and/or IC. The first end of the matching element 160 is connected to the first end of the first radiation pattern 130. The second end of the matching element 160 is connected to the first end of the second radiation pattern 140. The matching element 160 is connected to both ends of the loop pattern 110 formed by the first radiation pattern 130 and the third radiation pattern 150, and is connected to the main NFC radiation pattern 24 and the loop pattern of the holder 10. Match the resonance frequency and impedance between (110).

The booster antenna 100 for a mobile terminal according to an embodiment of the present invention may be configured in the form of a sheet attached to the rear of the mobile terminal 20 or the inner surface of the case 30. At this time, the booster antenna 100 for a mobile terminal is attached to the rear of the mobile terminal 20 by the adhesive force of the adhesive sheet 180.

To this end, referring to FIG. 8, the booster antenna 100 for a mobile terminal may be configured to further include a coverlay sheet 170 and an adhesive sheet 180.

Coverlay sheet 170 is disposed on the first side of base substrate 120. The coverlay sheet 170 is disposed on the first surface of the base substrate 120 on which the first radiation pattern 130 and the second radiation pattern 140 are formed, and protects the first radiation pattern 130.

A guide mark may be formed on the surface of the coverlay sheet 170 to guide the attachment position of the booster antenna 100 for a mobile terminal. The main NFC radiation pattern 24 built into the mobile terminal 20 may have different mounting positions and sizes depending on the model, manufacturer, etc. The booster antenna 100 for a mobile terminal can be attached to an accurate position through the guide mark formed on the surface of the coverlay sheet 170. Here, the exact location means a location where the main NFC radiation pattern 24 and the loop pattern 110 overlap at least partially.

The adhesive sheet 180 is disposed on the second side of the base substrate 120. The adhesive sheet 180 is disposed on the second side of the base substrate 120 on which the third radiation pattern 150 is formed, so that the booster antenna 100 for a mobile terminal can be attached to the rear of the mobile terminal 20. .

An adhesive for adhesion to the base sheet is applied to the first side of the adhesive sheet 180. An adhesive for adhering the booster antenna 100 for a portable terminal to the surface of the holder 10 is applied to the second surface of the adhesive sheet 180. At this time, for example, a detachable pressure-sensitive adhesive is applied to the second surface of the adhesive sheet 180.

Referring to FIG. 9, the booster antenna 100 for a mobile terminal is attached to the rear of the mobile terminal 20 through an adhesive sheet 180. At this time, the mounting location and size of the booster antenna 100 for a mobile terminal may vary depending on the model and manufacturer of the mobile terminal 20.

Referring to FIG. 10, the booster antenna 100 for a mobile terminal is configured such that a coverlay sheet 170 is disposed on the first and second surfaces of the base substrate 120, respectively, and is molded on the case 30. ) and may be configured integrally with the case 30. At this time, since the mounting position of the main NFC radiation pattern 24 of the mobile terminal 20 is different depending on the model and manufacturer, the molding position of the booster antenna 100 for the mobile terminal is also different depending on the model and manufacturer.

At this time, referring to FIG. 11 , the loop pattern 110 overlaps at least partially with the main NFC radiation pattern 24 of the mobile terminal 20 to form an overlap area A1. The loop pattern 110 operates as an auxiliary radiator of the main NFC radiation pattern 24 due to the coupling effect in the overlap area A1. Here, in FIG. 11, the loop pattern 110 is shown to form one overlapping area A1 with the main NFC radiation pattern 24, but it is not limited to this and may be configured to form two or more overlapping areas.

Accordingly, the booster antenna 100 for a mobile terminal can extend the recognition distance of the main NFC radiation pattern 24 of the mobile terminal 20 and minimize the unrecognized area of the main NFC radiation pattern 24.

For example, referring to FIG. 12, the wireless power receiving coil 22 is placed in the center based on the rear of the mobile terminal 20, and the small-sized main NFC radiation pattern 24 is located on the rear of the mobile terminal 20. It is assumed to be placed at the top right based on .

When the mobile terminal 20 is used alone, the wireless power transmission coil 12 of the holder 10 and the wireless power reception coil 22 of the mobile terminal 20 overlap at least partially to enable wireless power transmission. However, the main NFC radiation pattern 24 of the mobile terminal 20 is bound to be placed in the inner peripheral area (i.e., unrecognized area) of the NFC radiation pattern 14 of the holder 10, so it is not connected to the holder 10 or the vehicle. Short-distance communication between the portable terminals 20 becomes impossible, and the portable terminal 20 cannot replace the fob.

On the other hand, in the case of the mobile terminal 20 to which the booster antenna 100 for a mobile terminal is attached (placed) according to an embodiment of the present invention, the loop pattern 110 of the booster antenna 100 for a mobile terminal is the main NFC radiation. It partially overlaps with the pattern 24 to form an overlapping area A2. Accordingly, the loop pattern 110 operates as an auxiliary radiator of the main NFC radiation pattern 24 due to the coupling effect in the overlap area A2.

Accordingly, as the mobile terminal 20 is mounted on the holder 10, the loop pattern 110 of the booster antenna 100 for the mobile terminal overlaps the NFC radiation pattern 14 of the holder 10, creating an overlap area A3. By forming this, short-distance communication between the holder 10 (or vehicle) and the portable terminal 20 is possible, and the portable terminal 20 can replace the fob.

In addition, the booster antenna 100 for a mobile terminal has the size and/or mounting position of the main NFC radiation pattern 24 on which the holder 10 is mounted on the mobile terminal 20, and the mounting position (direction) of the mobile terminal 20. Regardless, near field communication (NFC) can always be enabled at a certain level.

As described above, the booster antenna 100 for a mobile terminal according to an embodiment of the present invention is disposed on the rear of the mobile terminal 20 to increase the recognition distance of the main NFC radiation pattern 24, thereby The alignment of the mobile terminal 20 allows short-range communication (NFC) between the holder 10 and the mobile terminal 20, allowing the mobile terminal 20 to replace the fob of the vehicle.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention. Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but are for illustrative purposes, and the scope of the technical idea of the present invention is not limited by these embodiments. The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

10: Holder 12: Wireless power transmission coil
14: NFC radiation pattern 20: mobile terminal
22: Wireless power receiving coil 24: Main NFC radiation pattern
30: Case 100: Booster antenna for mobile terminal
110: Loop pattern 120: Base material
130: first radiation pattern 140: second radiation pattern
150: third radiation pattern 160: matching element
170: Coverlay sheet 180: Adhesive sheet

Claims (15)

In the booster antenna for a mobile terminal disposed on the rear of the mobile terminal,
Base substrate; and
A loop pattern formed on the base substrate and configured to operate as an auxiliary radiator of the main NFC radiation pattern built into the mobile terminal when the booster antenna for the mobile terminal is disposed on the rear of the mobile terminal,
The loop pattern is a booster antenna for a mobile terminal where at least part of the loop pattern overlaps with a main NFC radiation pattern built into the mobile terminal. According to paragraph 1,
The loop pattern is a booster antenna for a mobile device that forms one or more overlapping areas with the main NFC radiation pattern as the booster antenna for a mobile device is attached to the mobile terminal. According to paragraph 1,
The loop pattern is wound along an imaginary first winding axis orthogonal to the base substrate,
The first winding axis is parallel to the winding axis of the main NFC radiation pattern, and is spaced apart from the winding axis of the main NFC radiation pattern. According to paragraph 1,
The center of the loop pattern is a booster antenna for a mobile terminal spaced apart from the center of the main NFC radiation pattern. According to paragraph 1,
The loop pattern is a booster antenna for a mobile terminal having an area different from that of the main NFC radiation pattern. According to paragraph 1,
The loop pattern is a booster antenna for a mobile terminal having an area smaller than that of the main NFC radiation pattern. According to paragraph 1,
A booster antenna for a mobile terminal further comprising a matching element disposed on the base substrate and connected to the loop pattern, and matching a resonance frequency and impedance between the main NFC radiation pattern and the loop pattern. According to paragraph 1,
The loop pattern is,
a first radiation pattern disposed on a first side of the base substrate and having a loop shape wound along a virtual first winding axis orthogonal to the base substrate;
a second radiation pattern disposed to be spaced apart from the first radiation pattern on the first side of the base substrate; and
A booster antenna for a mobile terminal disposed on a second surface of the base substrate and including a third radiation pattern connecting the first radiation pattern and the second radiation pattern. According to clause 8,
A first end of the first radiation pattern is connected to a first end of the matching element,
A booster antenna for a mobile terminal, wherein the second end of the first radiation pattern is connected to the first end of the third radiation pattern through a first via hole. According to clause 8,
The first end of the second radiation pattern is connected to the second end of the matching element,
A booster antenna for a mobile terminal, wherein the second end of the second radiation pattern is connected to the second end of the third radiation pattern through a second via hole. According to clause 8,
The first winding axis is a booster antenna for a mobile terminal spaced apart from the winding axis of the main NFC radiation pattern. According to clause 8,
The first radiation pattern is a booster antenna for a mobile terminal having an area smaller than that of the main NFC radiation pattern. According to paragraph 1,
The booster antenna for a mobile terminal further comprising an adhesive sheet disposed on a second side of the base substrate facing the rear of the mobile terminal or the inner surface of a case fitted into the rear of the mobile terminal. According to clause 13,
An adhesive is disposed on a first side of the adhesive sheet, and the first side of the adhesive sheet is adhered to one of the rear surface of the mobile terminal and the inner surface of the case. According to paragraph 1,
A booster antenna for a mobile terminal, wherein the base material and the loop pattern are molded into a case fitted to the rear of the mobile terminal and integrated with the case.