KR20150021679A - antenna module and portable terminal device using it - Google Patents

Abstract

Provided are an antenna module and a portable terminal device. The antenna according to an embodiment of the present invention comprises a radiator; a carrier supporting the radiator, a feeding unit connected to the radiator and transferring a signal to the radiator, and an inverse impedance matching unit connected to the feeding unit and providing inverse impedance for removing a reactance component among impedance components of the radiator, wherein the radiator is a linear metal thin film formed on the surface of the carrier and having at least one curved portion. Thus, a user may secure a wide band of the antenna.

Description

TECHNICAL FIELD [0001] The present invention relates to an antenna module and a portable terminal device using the antenna module.

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an antenna module and a portable terminal device using the antenna module, and more particularly, to an antenna module capable of realizing a wide band performance and a portable terminal device using the antenna module.

Various kinds of electronic devices have been developed and popularized by the development of electronic technology. Especially, users can easily access small portable electronic devices in daily life.

On the other hand, along with miniaturization of the portable terminal device, the volume of the antenna mounted in the portable terminal device is also decreasing, but the bandwidth used for LTE (Long Term Evolution) support is increasing.

However, regardless of the type or technique used to implement the antenna, the antenna must generally be greater than one quarter of the wavelength to be able to operate correctly. Therefore, when the size of the antenna is much smaller than the wavelength (i.e., the size of the antenna is smaller than 1/4 of the wavelength), the performance of the antenna is proportional to the size.

Therefore, there is a need for a technique capable of securing a wide bandwidth even in an antenna having a small size compared to a wavelength. In particular, in order to overcome the performance limitations of a small antenna and to secure a wide band, a negative impedance matching technique is used. However, there is a need for an antenna design technique capable of maximizing the effect of the reverse impedance matching technique.

It is an object of the present invention to provide an antenna module and a portable terminal device capable of securing a wideband using a negative impedance matching technique.

According to an aspect of the present invention, there is provided an antenna module including a radiator, a carrier for supporting the radiator, a power feeder connected to the radiator for transmitting a signal to the radiator, And an inverse impedance matching unit for providing an inverse impedance for eliminating a reactance component of an impedance component of the radiator, wherein the radiator is formed on a surface of the carrier, the line-shaped metal having at least one bent portion And is a thin film.

The power supply unit may be connected to the radiator through the carrier.

The radiator is formed in a first direction on a surface of the carrier and is formed in a first part connected to the feed part and in a second direction perpendicular to the first direction on the surface of the carrier, And a second part connected to the first part.

The radiator may include a first part formed on a surface of the carrier and connected to the feed part, a second part formed on a surface of the carrier in a direction parallel to the first part, And a third part connecting the second part.

The radiator may be formed in a first direction on a surface of the carrier and may include a first part connected to the feed part and a second part formed in a second direction perpendicular to the first direction on the surface of the carrier, And a third part formed in the first direction at a position spaced apart from the first part on the surface of the carrier and connected to the second part.

The radiator includes a first part formed on a surface of the carrier and connected to the feed part, a second part formed in a direction parallel to the first part on the surface of the carrier, A third part connecting the first end of the second part and a fourth part extending from the second end of the second part in a direction parallel to the third part, have.

According to another aspect of the present invention, there is provided a portable terminal device including an antenna module and a board portion on which the antenna module is mounted, the antenna module including a radiator, a carrier for supporting the radiator, And an inverse impedance matching unit connected to the feeding unit and providing an inverse impedance for removing a reactance component of an impedance component of the radiator, wherein the radiator is connected to the surface of the carrier Shaped metal thin film having at least one bent portion formed on the substrate.

The power supply unit may be connected to the radiator through the carrier.

The radiator may be formed in a first direction on a surface of the carrier and may include a first part connected to the feed part and a second part formed on a surface of the carrier in a second direction perpendicular to the first direction, And a second part connected to the first part.

The radiator includes a first part formed on a surface of the carrier and connected to the feed part through the hole, a second part formed in a direction parallel to the first part on the surface of the carrier, One part and a third part connecting the second part.

The radiator may include a first part formed in a first direction on a surface of the carrier and formed in a second direction perpendicular to the first direction on a surface of the carrier, And a third part formed in the first direction at a position separated from the first part on the surface of the carrier and connected to the second part on the surface of the carrier, And a shorting part connected to the end.

The radiator includes a first part formed on a surface of the carrier and connected to the feed part, a second part formed in a direction parallel to the first part on the surface of the carrier, A third part connecting the first end of the second part and a fourth part extending from the second end of the second part in a direction parallel to the third part, And a shorting part connected to an end of the fourth part.

According to various embodiments of the present invention, it is possible to provide an antenna module capable of ensuring a broadband using a negative impedance matching technique and a portable terminal device using the antenna module.

1 is a block diagram showing the configuration of an antenna module according to an embodiment of the present invention;
2 to 5 are views showing a structure of a radiator of an antenna module according to each embodiment of the present invention,
6 is a view showing an example of the shape of a carrier and a radiator of an antenna module which can be mounted on the upper end of the cellular phone,
7 and 8 are diagrams showing circuits of an inverse impedance matching unit,
FIGS. 9 and 10 are graphs illustrating the effect of the embodiment of the present invention over an inverted F antenna; and FIG.
11 is a diagram illustrating a configuration of a portable terminal device according to an embodiment of the present invention.

Various embodiments of the present invention will now be described in more detail with reference to the accompanying drawings. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather unclear. The following terms are defined in consideration of the functions of the present invention, and these may be changed according to the intention of the user, the operator, or the like. Therefore, the definition should be based on the contents throughout this specification.

1 is a block diagram showing the configuration of an antenna module 100 according to an embodiment of the present invention. As shown in FIG. 1, the antenna module 100 includes a radiator 110, a carrier 120, a feeder 130, and an inverse impedance matching unit 140. The antenna module 100 is mounted on various devices such as a mobile phone and a tablet PC, and is a module for transmitting and receiving various signals. The antenna module 100 includes not only an antenna but also various circuit elements for driving the antenna. The antenna module 100 may be implemented as a single independent unit but is not necessarily limited thereto and may be configured to have a configuration such as the feeding part 130 and the inverse impedance matching part 140 in the antenna module 100, Elements may be disposed outside the antenna module 100 and used in connection with the radiator 110 and the carrier 120. [

The radiator 110 is a component for radiating an electromagnetic signal. The radiator 110 may be embodied as a metal film patterned in a predetermined shape on the surface of the carrier 120. Specifically, the radiator 110 may be embodied as a line-shaped metal thin film having at least one bent portion. The number of the bent portions can be variously designed according to the embodiment, and the bending angle can be designed variously. A description of the shape of the specific radiator 110 will be described later.

Further, the radiator 110 is connected to the power feeder 130. The power feeder 130 supplies electromagnetic energy to the radiator 110 and the radiator 110 that receives the electromagnetic energy can radiate electromagnetic signals in the form of electromagnetic waves.

The carrier 120 supports the radiator. The carrier 120 may be a non-insulating material such as plastic. A radiator 110 in the form of a thin metal film may be mounted on one side of the carrier 120. Also, at least one hole may be formed in the carrier 120. The radiator 110 may be connected to the power feeder 130 disposed on the opposite side of the carrier 120 through a hole penetrating the carrier 120.

The feeding part 130 is connected to the radiator 110 to transmit a signal to the radiator 110 and supply electromagnetic energy. The position of the feeding part 130 may be a surface opposite to the radiator 110 with respect to the carrier 120 and may be disposed on the side surface of the carrier 120. The power feeder 130 may be connected to the radiator 110 through the hole as described above. In this case, the feeding part 130 may be embodied as a metal connector or clip formed along the side surface inside the hole, or may be embodied as a metal wire passing through the hole in a state spaced apart from the side surface inside the hole have.

The inverse impedance matching unit 140 is connected to the feeder 130 and provides an inverse impedance for removing the reactance component of the impedance component of the radiator 110. [ In other words, the inverse impedance matching unit 140 can implement non-Foster matching that maximizes the radiation effect by canceling the reactance component of the radiator 110.

Specifically, when the reactance component of the impedance component of the radiator 110 becomes zero, a resonance occurs in which the antenna can most effectively transmit and receive radio waves of a specific wavelength. That is, when the reactance component becomes 0, the efficiency of the antenna is improved, the antenna is not lost, and the broadband can be secured.

Accordingly, the inverse impedance matching unit 140 may provide an inverse impedance to make the reactance component appear to have been removed from the equivalent circuit of the antenna. The detailed configuration example of the inverse impedance matching unit 140 will be described later.

2 to 5 are views showing the structure of the radiator 110 according to each embodiment of the present invention. As described above, the radiator 110 may be implemented in a line shape having at least one bent portion. 2 to 5, the upper direction may be the upper end direction of the device on which the antenna module 100 is mounted.

2 shows a case where the radiator 110 has one bent portion. That is, according to FIG. 2, the radiator 110 may be implemented in an "L" shape.

2, the radiator 110 is formed in a first direction on the surface of the carrier 120 and includes a first part 210 and a carrier 120 connected to the feed part 130 through holes, And a second part 220 formed in a second direction perpendicular to the first direction on the surface of the first part 210 and connected to the first part 210.

The other end not connected to the second part 220 of the first part 210 may be a part 211 connected to the feed part 130.

The radiator 110 may include a bent portion in which the first part 210 and the second part 220 form an angle of 90 degrees with respect to each other and may be connected. Although the first part 210 and the second part 220 are described in FIG. 2 for the sake of convenience, the first part 210 and the second part 220 may be made of an integrated material. That is, the radiator 110 may be in the shape of one line that is not physically divided.

3 shows an example of a radiator 110 having two bent portions.

3, the radiator 110 may be divided into a first part 310, a second part 320, and a third part 330 on the basis of the bent part.

The first part 310 may be connected to the feed part 130 through a hole and the second part 320 may be formed in a direction parallel to the first part 310 on the surface of the carrier 120. The third part 330 may connect the second part 320 and the first part 310. The third part 330 may be connected to the first part 310 and the second part 320 by forming a bent part having an angle of 90 degrees with the first part 310 and the second part 320, respectively.

The other end which is not connected to the third part 330 of the first part 310 may be a part 311 connected to the feed part 130.

The lengths of the first part 310 and the second part 320 may be different from each other and the length of the first part 310 may be shorter than the length of the second part 320. The third part 330 may have a length similar to that of the first part 310 and a length of the second part 320 that is longer than the length of the first part 310 and the third part 330 have.

Fig. 4 shows another example of a radiator having two bent portions.

As shown in FIG. 4, the radiator 100 may be divided into a first part 410, a second part 420, and a third part 430. The first part 410 is formed in a first direction on the surface of the carrier 120 and may be connected to the feed part 130 through a hole. 3, the first part 310 of FIG. 3 is aligned in the left direction with respect to the hole, but the first part 410 of the embodiment of FIG. 4 aligns with the hole in the upward direction There is a difference.

The second part 420 is formed on the surface of the carrier 120 in a second direction perpendicular to the first direction and connected to the first part 410. In addition, the third part 430 is connected to the first part 410 and is formed at a position spaced in the first direction, the second part (42 0).

The other end which is not connected to the second part 420 of the first part 410 may be the part 411 connected to the feed part 130 and the other part of the first part 410 and the third part 430 The lengths may be the same or similar. The end of the third part 430, which is the farthest from the part 411 connected to the feeding part 130 in the radiator of FIG. 4, is connected to a ground port connected to the board part (not shown) . Thus, one loop is formed.

5 shows an example of a radiator 110 having three bent portions.

As shown in FIG. 5, the radiator 100 may be divided into a first part 510, a second part 520, a third part 530, and a fourth part 540. The first part 510 is formed on the surface of the carrier 120 and can be connected to the feed part 130 through the hole. The first part 510 may be aligned to the left with respect to the hole as in the embodiment shown in FIG.

The second part 520 may be formed on the surface of the carrier 120 in a direction parallel to the first part 510 and the third part 530 may be formed on the surface of the carrier 120 in the first and second parts 510, The first end of the second electrode 520 may be connected.

The fourth part 540 may extend from the second end of the second part 520 in a direction parallel to the third part 530.

The other end that is not connected to the third part 430 of the first part 410 may be the part 411 connected to the feed part 130.

The lengths of the first part 510, the third part 530 and the fourth part 540 are similar and the length of the second part 520 is equal to the length of the first part 510, the third part 530, The radiator 110 may have a rectangular shape in which a part of one corner is opened, as the shape of the radiator 110 is longer than that of the fourth part 540.

The end of the fourth part 540, which is the farthest from the part 511 connected to the feeding part 130 in the radiator of FIG. 5, is connected to a ground port connected to the board part (not shown) . Thus, one loop is formed.

Accordingly, the antennas of FIGS. 4 and 5 may be loop antennas.

2 to 5, the widths of the parts of the radiator 110 are the same, but the widths of the parts may be set individually, and the number of the bent parts may be adjusted according to the shape of the carrier 120 .

6 shows an example of the shape of the carrier 120 and the radiator 110 of the antenna module which can be mounted on the upper end portion of the cellular phone. According to Fig. 6, the carrier 120 is designed in a shape corresponding to the outer shape of the cellular phone, and is mounted on the cellular phone. The radiator 110 may be mounted on the carrier 120. 6, various modules such as a speaker, a flash module, a camera module, a microphone module, and the like may be mounted together with the carrier 120 according to the position of the carrier 120. FIG.

The remaining portion except for the radiator 110 may be an insulator such as plastic, and the radiator 110 may be a thin metal film that is electrically conductive.

6, a hole 610 may be present at one point of the carrier 120, and the radiator 110 may be coupled to the radiator 100 through a square hole 610, May be connected to the front portion (130).

As a result, by using the radiator 110 having a structure as shown in FIGS. 2 to 6, it is possible to realize an antenna in which the reverse impedance matching technique can exhibit the maximum effect. The effect obtained by using the above-described structure of the radiator 110 will be described later.

On the other hand, the inverse impedance matching unit 140 is connected to one end of the feed unit 130. That is, one end of the feeder 130 is connected to the inverse impedance matching unit 140, and the other end is connected to the radiator 110.

7 and 8 are views showing examples of circuits of the inverse impedance matching unit 140 in detail. 7 and 8 illustrate a negative impedance converter circuit in which a positive inductance value is represented by a negative inductance value and a positive positive capacitance value is represented by a negative -) capacitance value.

The negative impedance converter circuit may be implemented by connecting an inductor and a capacitor in series as shown in FIG. 7, or may be implemented by connecting an inductor and a capacitor in parallel as shown in FIG.

7 and 8, the circuit of the inverse impedance matching unit 140 may be a negative impedance inverter circuit. The negative impedance inverter circuit converts positive (+) inductance value into negative (-) capacitance value and positive (+) capacitance value into negative (-) inductance value.

In addition, the circuit of the inverse impedance matching unit 140 may be located at the input load of the antenna module.

By the above-described negative impedance circuit, the user can remove the reactance component of the impedance component of the radiator 110, thereby widening the range of the resonance frequency. That is, when the antenna is a resonance frequency, the radio waves of a specific wavelength are most effectively transmitted and received. Therefore, if the range of the resonance frequency is broadened, the range of the frequency at which the radio waves can be effectively transmitted and received is widened.

FIGS. 9 and 10 are graphs showing the effect of the embodiment according to the present invention over an inverted F antenna. FIG.

9 is a graph showing the radiation efficiency of the antenna. Radiation Efficiency refers to the It means the efficiency that the amount of radiated power excluding the loss occurred is calculated in proportion to the input power. Therefore, the higher the radiation efficiency, the better the performance of the antenna.

The abscissa of the graph represents the frequency and the unit is MHz . Although the maximum value of the radiation efficiency is the largest in the graph 900 of the inverted-F antenna, the range of frequencies where the radiation efficiency is relatively high (for example, the radiation efficiency is 35% or more) The frequency is between 800 MHz and 900 MHz. Therefore, when a frequency value other than the frequency between 800 MHz and 900 MHz is applied, the radiation efficiency is rapidly deteriorated.

However, the graph 910 of the first embodiment is a graph of radiation efficiency when the antenna of the type shown in FIG. 2 or 3 is implemented, and the graph 920 of the second embodiment is the graph of FIG. 4 or FIG. 5 It is a graph of radiation efficiency when an antenna of the same type is implemented.

That is, the graphs 910 and 920 of the first and second embodiments show that the maximum value of the radiation efficiency is smaller than that of the inverted-F antenna, but the frequency of the radiation efficiency is relatively high (for example, The efficiency is more than 35%) is wider than the inverted-F antenna (Inverted-F Antenna). Also, unlike the graph 900 of the inverted F antenna, the phenomenon of rapid radiation efficiency is reduced.

10 is a graph showing the radiation resistance according to the frequency of the antenna. The power consumed in the radiation resistance becomes the electric power of the actual radio wave.

The horizontal axis of the graph represents the frequency, and the unit is MHz as shown in FIG. As shown in FIG. 9, the graph of the first embodiment is a graph of radiation efficiency when the antenna of FIG. 2 or 3 is implemented, and the graph of the second embodiment is similar to that of FIG. 4 or 5 Of the antenna is implemented.

In the graph 1000 of Inverted-F Antenna shown in FIG. 10, the radiation resistance has a small value at most frequencies, but at a frequency at which the radiation efficiency becomes maximum, the radiation resistance also sharply increases and becomes a maximum value. That is, it has a larger radiation resistance than the graphs 1010 and 1020 of the first embodiment and the second embodiment, but has a wide variation range. Therefore, there is a disadvantage that the radiation resistance of a portion other than a certain frequency is very small.

However, in the graph 1010 of the first embodiment, the value of the radiation resistance at the entire frequency is small, but in the frequency band excluding the frequency at which the graph 1000 of the inverted-F antenna is the maximum, It can have a larger value of radiation resistance.

The graph 1020 of the second embodiment also shows that the value of the radiation resistance at the entire frequency is greater than the graph 1000 of the inverse F antenna 1000 while maintaining the value of the maximum value of the inverse F antenna graph 1000 and the mean value of the first embodiment ), There is no rapid change phenomenon.

As described above, by using the radiator 110 having the shapes shown in FIGS. 2 to 6 and the inverse impedance matching unit 140 providing the reverse impedance, the range of the frequency having the radiation efficiency of more than a predetermined value is wide, It is possible to realize an antenna which is smaller than the maximum value of the radiation resistance of the inverted F antenna but which is larger than the minimum value of the radiation resistance of the inverted F antenna and does not change rapidly according to the change of the value of the frequency.

11 is a diagram showing a configuration of a portable terminal device 200 according to an embodiment of the present invention. The portable terminal device 200 shown in FIG. 11 includes an antenna module 100 and a board unit 150.

The board unit 150 is a component for mounting the antenna module 100 and the various pixel elements. The board unit 150 may be provided with a ground port (not shown) connected to an end of the loop antenna. Specifically, if the radiator 110 is implemented as shown in FIG. 4, the end of the third part 430 may be connected to a short-circuit part (not shown). If the radiator 110 is implemented as shown in FIG. 5, 4 The end of the part 540 may be connected to a shorting part (not shown). The board portion 150 may be made of a metal or the like.

The antenna module 100 includes a radiator 110, a carrier 120, a feeder 130, and an inverse impedance matching unit 140, as described above.

The radiator 110 may be formed on the surface of the carrier 120 and may be a line-shaped metal thin film having at least one bent portion. Specifically, the radiator 110 may be a metal thin film having a shape as shown in FIGS.

The carrier 120 supports the radiator. The carrier 120 may be a non-insulating material such as plastic. The radiator 110 may be connected to the power feeder 130 through a hole passing through the carrier 120. The radiator 110 may be a metal thin film radiator.

The feeder 130 included in the board 150 may connect the radiator 110 and the board 150 to transmit signals to the radiator 110.

The inverse impedance matching unit 140 may be connected to the feeder 130 to provide an inverse impedance for removing the reactance component of the impedance component of the radiator 110.

The shape of the radiator 110 included in the portable terminal device 200 may be implemented as shown in FIGS. Since the shape and operation principle of the radiator 110 have already been described above, a duplicate description will be omitted.

11, the antenna module 100 is directly mounted on the board 150. However, some of the components in the antenna module 100 may be mounted on the board 150. FIG.

That is, according to another embodiment of the present invention, the antenna module includes the radiator 110 and the carrier 120, and the feeding part 130 and the reverse impedance matching part 140 are mounted on the board part 150 do.

As described above, it is possible to increase the radiation effect while performing the broadband communication using the radiator having the shape suitable for the reverse impedance matching method.

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 construed as limiting the scope of the invention as defined by the appended claims. It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention.

100: antenna module 110: radiator
120: carrier 130: feeding part
140: an inverse impedance matching unit 150:
160: hole

Claims (12)

Radiators;
A carrier for supporting the radiator;
A power feeder connected to the radiator and transmitting a signal to the radiator;
And an inverse impedance matching unit coupled to the feed unit and providing an inverse impedance for removing a reactance component of an impedance component of the radiator,
The radiator includes:
Wherein the antenna module is a line-shaped metal thin film formed on a surface of the carrier and having at least one bent portion. The method according to claim 1,
And the power feeding part is connected to the radiator through the carrier. 3. The method of claim 2,
The radiator includes:
A first part formed in a first direction on the surface of the carrier and connected to the feed part; And
And a second part formed on a surface of the carrier in a second direction perpendicular to the first direction and connected to the first part. 3. The method of claim 2,
The radiator includes:
A first part formed on a surface of the carrier and connected to the feed part;
A second part formed on a surface of the carrier in a direction parallel to the first part;
And a third part connecting the first part and the second part. 3. The method of claim 2,
The radiator includes:
A first part formed in a first direction on the surface of the carrier and connected to the feed part;
A second part formed on a surface of the carrier in a second direction perpendicular to the first direction and connected to the first part;
And a third part formed in the first direction at a position spaced apart from the first part on the surface of the carrier and connected to the second part. 3. The method of claim 2,
The radiator includes:
A first part formed on a surface of the carrier and connected to the feed part;
A second part formed on a surface of the carrier in a direction parallel to the first part;
A third part connecting a first end of the first part and a first end of the second part;
And a fourth part extending from a second end of the second part in a direction parallel to the third part. In the portable terminal device,
An antenna module; And
And a board unit on which the antenna module is mounted,
The antenna module includes:
Radiators;
A carrier for supporting the radiator;
A feeder connected to the radiator to transmit a signal to the radiator; And
And an inverse impedance matching unit coupled to the feed unit and providing an inverse impedance for removing a reactance component of an impedance component of the radiator,
The radiator includes:
Shaped metal thin film formed on the surface of the carrier and having at least one bent portion. 8. The method of claim 7,
And the power supply unit is connected to the radiator through the carrier. 9. The method of claim 8,
The radiator includes:
A first part formed on a surface of the carrier in a first direction and connected to the feed part;
And a second part formed on a surface of the carrier in a second direction perpendicular to the first direction and connected to the first part. 9. The method of claim 8,
The radiator includes:
A first part formed on a surface of the carrier and connected to the feed part through the hole;
A second part formed on a surface of the carrier in a direction parallel to the first part;
And a third part connecting the first part and the second part. 9. The method of claim 8,
The radiator includes:
A first part formed in a first direction on the surface of the carrier and connected to the feed part;
A second part formed on a surface of the carrier in a second direction perpendicular to the first direction and connected to the first part; And
And a third part formed in the first direction at a position spaced apart from the first part on the surface of the carrier and connected to the second part,
Wherein,
And a shorting part connected to an end of the third part. 10. The method of claim 9,
The radiator includes:
A first part formed on a surface of the carrier and connected to the feed part;
A second part formed on a surface of the carrier in a direction parallel to the first part;
A third part connecting a first end of the first part and a first end of the second part;
And a fourth part extending from a second end of the second part in a direction parallel to the third part,
Wherein,
And a shorting part connected to an end of the fourth part.

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