KR100773143B1 - Wide band antenna of using coupled patch and wide band characterizing method thereof - Google Patents

Abstract

The present invention relates to a broadband antenna for a wireless communication terminal and a method for implementing the broadband characteristics thereof, the main radiation patch being connected to a feeder for supplying electrical energy to one surface of a PCB for a wireless communication terminal and shorted to the ground; And a couple patch having a predetermined width on a surface opposite to a surface on which the power feeding portion is located on the PCB, and having a conductor connected to the ground and an inductor.

As described above, when the broadband antenna according to the present invention is provided, it is possible to implement a multi-band antenna having a small antenna volume by solving a problem that it is difficult to secure the volume of the built-in antenna while making the design of the wireless communication terminal slim and small. In addition, the resonant frequency can be easily adjusted to provide a multiband or wideband antenna of a desired band.

Main radiation patch, coupled patch, feed, inductor, internal antenna, resonant frequency

Description

Wideband Antenna Using Couple Patch and Method of Implementing Broadband Characteristics {WIDE BAND ANTENNA OF USING COUPLED PATCH AND WIDE BAND CHARACTERIZING METHOD THEREOF}

1 is a view schematically showing an antenna embedded in a conventional mobile communication terminal,

FIG. 2 illustrates the structure of an antenna composed of a coupled patch for implementing broadband characteristics using a conventional coupling element developed to improve a problem of narrowband characteristics of a conventional antenna and its resonance characteristics. Drawing,

3 is a view showing an example of the structure of a broadband antenna according to the present invention,

FIG. 4 is a diagram illustrating a structure of a broadband antenna connected to a terminal patch including a couple patch PCB integrated antenna and an RF element, in which a feeder and a couple patch are formed on both sides of a PCB, as another embodiment according to the present invention. Drawing,

5 is a photograph illustrating a broadband antenna implementing a couple patch on the opposite side of the feed terminal on the terminal PCB according to the present invention,

FIG. 6 is a graph showing a photograph when the couple patch formed on the opposite side of the surface where the feed and short terminals are located is directly grounded and GND through the inductor, and a corresponding resonance characteristic thereof.

7 is a view illustrating a resonance characteristic according to the area of a couple patch as a broadband antenna having a couple patch according to the present invention;

8 is a broadband antenna according to the present invention, a photograph and a graph showing a change in resonance characteristics according to the connection position of the chip inductor between the couple patch and ground,

9 is a diagram illustrating a photograph of an antenna having a structure in which a couple patch is formed on an opposite side of an antenna PCB main radiation patch feeder according to the present invention, and a graph of resonance characteristics thereof;

10 is a photograph illustrating a structure in which a built-in antenna is coupled onto a PCB of a terminal according to the present invention, and a graph illustrating resonance characteristics of broadband characteristics thereof.

<Description of main parts of drawing>

220: power supply terminal, 210: short circuit terminal,

240: main radiation patch, 270: feeder, 280: short terminal, 250: ground,

275: coupled patch, 277: inductor

320: feed terminal, 310: short terminal, 340: the main radiation patch, 370: feed section

380: short terminal, 350: ground, 390: couple patch surface of the antenna PCB

360: Antenna PCB side with feed terminal

355: Main PCB and antenna PCB connection coaxial cable

365: terminal PCB, 375: couple patch, 377: inductor

The present invention relates to a broadband antenna for a mobile communication terminal, and more particularly, to a broadband antenna for a high quality mobile communication terminal having broadband characteristics in a small volume space by improving an antenna built in a mobile communication terminal by a couple patch. will be.

Currently, various mobile communication terminals have a monopole antenna having a quarter length of a used frequency wavelength (λ / 4, λ is a wavelength of a used frequency) and a helical antenna having an electrically corresponding length (λ / 4). Retractable antennas are commonly used.

However, in the case of a flexible antenna, there is an advantage in that the electrical performance of the antenna is excellent, but the antenna is protruded out of the phone, which is not only inconvenient, but also has a disadvantage in that the unit cost increases due to a large number of parts. In addition, to tune the SAR (Specific Absorption Rate), there are two drawbacks that must be considered when the whip is inserted into the inside of the phone and when the whip is drawn out.

In the GSM-based countries, mobile phones do not use telescopic antennas, but helical antennas with electrical lengths of λ / 4, except for whips, are used. However, the fixed antenna has the advantage that the unit cost is low, but the fixed antenna also protrudes to the outside of the terminal has the disadvantage of causing inconvenience when carrying.

In the case of the flexible antenna and the fixed antenna, the antenna protrudes outward from the terminal, so that many parts are required, and there are many difficulties in miniaturizing the terminal, and there is a risk of damage, in particular, the inconvenience of carrying. .

For this reason, the research on technology that allows the use of the antenna inside the mobile communication terminal by removing the existing external type from the antenna is actively underway. As a result of this research, various types of internal antennas have been developed and used.

Current built-in antennas can be broadly classified into a microstrip patch antenna using a printed circuit technology, a ceramic antenna using a high dielectric ceramic, and a planar inverted F antenna.

However, the microstrip patch antenna has an advantage of facilitating frequency tuning, bandwidth expansion, etc. using various slots and stacking techniques, but has a disadvantage in that the antenna volume is greatly increased. In addition, since the ceramic antenna uses a high dielectric material, it is possible to reduce the antenna size. However, the ceramic antenna has a disadvantage in that it is difficult to use in a system requiring a wide band characteristic or a multi band characteristic due to the narrow bandwidth.

On the other hand, the inverted F-type antenna has a shorting pin adjacent to the feed point has the advantage of reducing the size of the entire antenna has been widely used as a built-in antenna. The reverse F-type antenna has a large antenna characteristic depending on the distance between the radiation patch and the PCB and the size of the antenna. A conventional reverse F-type antenna will be described in detail with reference to the accompanying drawings.

1 is a view schematically showing an antenna embedded in a conventional mobile communication terminal.

As shown in the figure, the built-in inverted-F antenna is grounded to the conductor layer 10, the conductor layer 10 is fixed to the dielectric 15 having a predetermined height, and the top of the dielectric 15 conductive A radiation patch 14 having a '13'-shaped slot 13 formed by printing a sieve and etching, a feed pin 19 for supplying current to the radiation patch 14, and the radiation patch ( And a shorting pin 17 for shorting the current of 14).

The radiation patch 14 is generally formed by printing a conductor on a dielectric 15 such as a PCB substrate. When the radiation patch 14 is etched, the radiation patch 14 may form a '13' shaped slot 13. The radiation patch 14 is connected to one end of the feed pin 19, the other end of the feed pin 19 is connected to the feed pad 21. Accordingly, current is applied to the radiation patch 14 by the feed pin 19.

The shorting pins 17 are connected to the radiation patch 14 and the conductor layer 10 for grounding, respectively, to short-circuit the currents of the two paths separated by the slots 13.

More specifically, when describing the operation relationship of the built-in antenna, when a current is applied to the radiation patch 14 through the feed pin 19, the current is in the inner and outer two paths of the 'b' shaped slot 13 It flows separately. The current path inside the slot 13 resonates the frequency of the high frequency band, and the current path outside the slot 13 resonates the frequency of the low frequency band.

That is, one of the two paths resonates the low frequency low frequency, and the signal of the shorter path resonates the high frequency. At this time, the desired resonance characteristics such as a double band or a multi band can be obtained according to the length, position, and shape of the slot 13, and the capacitance is controlled by adjusting the gap between the conductor layer 10 and the radiation patch 14 for grounding. The impedance can be varied by adjusting the capacitance component.

However, the above-described conventional built-in inverted F antenna has a disadvantage in that the bandwidth is very narrow and there are many limitations in the use of the service having a wide bandwidth. In particular, although the co-polarization characteristic is rather excellent on the radiation pattern, the cross-polarization characteristic orthogonal to the co-polarization at 90 ° is remarkably inferior. In addition, a fading phenomenon in which the reception power level of the portable mobile communication terminal decreases instantaneously occurs, which causes a lot of restrictions on the use of the portable mobile communication terminal.

FIG. 2 is a diagram illustrating the structure of an antenna composed of a coupled patch and its resonance characteristics for implementing broadband characteristics using a conventional coupling device developed to improve the problems of such narrowband characteristics. .

As shown in FIG. 2A, the main patch 140 is composed of a radiator connecting the feeding part 110 and the shorting part 1 130, and a coupled patch 170. The radiator is disposed near the power feeding unit 110 to be fed by a coupling feeding, and has a shorting unit 2 120 shorting one side. As shown in FIG. 2B, it can be seen that the resonance characteristic 150 due to the main patch and the resonance characteristic 160 due to the couple patch are shown.

As described above, the conventional broadband or multi-band antenna requires a couple element in addition to the main patch, so that the size of the antenna is increased, which is not suitable for a small antenna.

In addition, if the volume of the antenna is not large enough, even if the double resonance is performed in the range of DCS1800 (1710MHz ~ 1880MHz) to UMTS (1920MHz ~ 2120MHz), the coupling between the two resonant poles does not occur properly. The voltage standing wave ratio (VSWR) characteristic is often poor in the frequency band over. Therefore, there is a problem that the antenna of such a structure is not suitable for a small wireless communication terminal.

As described above, in the antenna having a multi-band characteristic, it is possible to solve the problem of securing the space by a couple patch and to provide a high quality antenna having the multi-band characteristic, and to easily adjust the resonance frequency of the antenna, It is an object to be able to provide an antenna of a desired band.

According to a first aspect of the present invention, there is provided an antenna for a wireless communication terminal, comprising: a main radiation patch connected to a feeding part for supplying electrical energy to one surface of a PCB for a wireless communication terminal and shorted to the ground; And a couple patch formed of a conductor connected to the ground and an inductor having a predetermined width on a surface opposite to a surface on which the power supply unit is located on the PCB.

In addition, the inductor is preferably a chip inductor, it is also preferable that the resonant frequency is adjusted according to the length or area of the couple patch. In addition, the resonance frequency may be adjusted according to the length or area of the couple patch, and the resonance frequency may be adjusted according to the position of the inductor.

According to a second aspect of the present invention, an antenna for a wireless communication terminal is connected to a feeder located on one surface of an antenna PCB, and a predetermined width is provided on an opposite surface of the antenna PCB on which the main radiation patch and short circuit to ground are located. And a couple patch formed of a conductor connected to the ground and an inductor, wherein the antenna PCB is connected to a terminal PCB having an RF element through the feeder.

Here, it is also preferable that the antenna PCB and the terminal PCB are connected by a coaxial cable, and the inductor is a chip inductor. In addition, the resonance frequency can be adjusted according to the area of the couple patch,

Preferably, the resonance frequency is adjusted according to the area of the couple patch, and the resonance frequency is adjusted according to the position of the inductor.

On the other hand, a third aspect of the present invention is a method for implementing the broadband characteristics of the antenna, in the method for implementing the broadband characteristics of the antenna by the coupling element, a feeder connected to the main patch located on one side of the terminal PCB Located on the opposite side, a couple patch made of a conductor having a predetermined width is connected to ground and an inductor.

In addition, a fourth aspect of the present invention is a method for implementing a wideband characteristic of an antenna, which is connected to a feeder for supplying electrical energy to one surface of an antenna PCB in a method for implementing a wideband characteristic of an antenna by a coupling element. A couple patch consisting of a main radiation patch shorted to ground and a conductor having a predetermined width on the opposite side of the PCB on which the feeder is located is connected to ground and an inductor, and the antenna PCB is provided with an RF element through the feeder. It is characterized in that the internal antenna PCB is connected to.

Here, the resonant frequency is preferably changed according to the area of the couple patch, the resonant frequency is adjusted according to the area of the couple patch, and the resonant frequency is also adjusted according to the position of the inductor.

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

3 is a diagram illustrating a structure of a broadband antenna according to the present invention. FIG. 3 (a) shows an example of a main radiation patch, and FIG. 3 (b) illustrates one surface of a terminal PCB in which a main radiation patch connected by a feed terminal and shorted to ground by a short terminal is located. 3 (c) is a diagram illustrating a state in which a couple patch is formed on an opposite surface corresponding to FIG. 3 (b).

As shown in FIG. 3 (a), the main radiation patch 240 is connected to a power supply 220 through a power supply unit and connected to a ground and a short circuit 210. As an example of such a structure, it is obvious that various types of antenna shapes can be formed.

The antenna structure according to the present invention is not implemented near the main radiator of the antenna, but implemented on a PCB of a wireless communication terminal or a mobile phone, but formed on the opposite surface 265 of the surface 260 where the feed terminal is located, The power supply terminal 270 is connected to the ground 250 and the inductor 277 without being connected to the power supply terminal 270 (see FIG. 3 (c)).

Here, the position of the couple patch 275 overlaps with the opposite surface 265 of the position where the power supply terminal 270 is located, so that resonance occurs due to electromagnetic coupling. That is, it is structured to form an electromagnetic coupling through the PCB substrate 260 having a constant thickness and dielectric constant between the feed terminal 270 and the couple patch 275 of the main radiation patch. In this case, the PCB substrate having a dielectric constant of about 4.4 is used.

By placing the couple patch 275 on the opposite side 265 of the feed terminal 270 of the terminal PCB, the relative voltage standing wave due to the spatial constraints and the increase of the antenna volume for side-by-side positioning on the same side of the main radiation patch. The problem of the deterioration of the ratio VSWR can be solved.

The resonance frequency of the couple patch can be basically adjusted to the length or area of the couple patch. That is, as the area of the couple patch increases, the resonance frequency moves to a low frequency.

In addition, as an important element of the present invention, it is possible to shift the resonance frequency of the couple patch according to the connection position of the couple patch and the ground. That is, by changing the connection position of the inductor, it is possible to induce a change in the resonance frequency in accordance with the change of the distance between the feed terminal and the short circuit position.

Here, it is preferable to use a chip inductor for the inductor 277, which has the advantage that the size of the chip inductor is small and the connection and movement of the chip are easy to adjust the frequency easily.

As shown in FIG. 3 (c), the resonance frequency of the couple patch 275 may be shifted according to the position of the chip inductor 277. The portion of the chip inductor 277 shorted to the ground 250 and the feed terminal may be moved. Since the resonant frequency varies considerably according to the distance of, it can be easily adjusted to the resonant frequency of the desired band.

FIG. 4 is a diagram illustrating a structure of a broadband antenna connected to a terminal PCB including an antenna PCB and an RF element, in which a feeder and a couple patch are formed on both sides of an antenna PCB, according to another embodiment of the present invention. to be.

Figure 4 (a) shows an example of the main radiation patch, Figure 4 (b) is a view illustrating the structure of a broadband antenna connected to the antenna fixing PCB and the terminal PCB is connected to the main radiation patch formed in the built-in antenna to be. FIG. 4 (c) is a diagram illustrating a structure in which a couple patch is implemented on an opposite side of a surface on which the feed part on the antenna PCB of FIG. 4 (b) is located.

As shown in Figure 4a, the main radiation patch 340 is formed in the antenna for the interior, can be formed of a metal material in a predetermined shape, the radiator 340 is fed to the feed 320 through the feed terminal, It is connected to the ground 310 through a short terminal.

In addition, as shown in FIG. 4B, the power supply terminal 370 may be connected to an RF cable such as a terminal PCB 365 having an RF element and a coaxial cable 355, and the main radiation patch may be connected to the ground 350 through a short terminal 380. do.

FIG. 4C is a view illustrating the structure of the reverse side of FIG. 4B, and as shown in FIG. 4C, on the opposite side 365 of the side where the feed terminal 370 of the antenna PCB is connected to the built-in antenna having the main radiation patch. A couple patch 375 having a predetermined width is formed, and the couple patch is connected to the ground 350 by an inductor 377.

The couple patch 375 is open with the surrounding ground plane 350 and must also open naturally with the feeder located on the opposite side, if the couple patch is directly grounded to the ground plane 350. It is not possible to resonate, because only the ground plane 350 has an extended effect. Therefore, when the couple patch 375 is connected to the ground plane 350 and the inductor 377, the couple patch 375 is resonated at a specific frequency by the couple patch 375, and radiates to the antenna at this resonant frequency.

In this case, the inductor 377 is preferably a chip inductor, in order to smoothly adjust the resonant frequency through the distance between the short-circuit terminal and the feeder part, and by using a small element, it can contribute to the miniaturization of the terminal. .

In addition, the resonance frequency of the couple patch can be basically adjusted to the length, area, or the like of the couple patch. That is, as the area of the couple patch increases, the resonance frequency moves to a low frequency. In addition, it is possible to shift the resonance frequency of the couple patch according to the connection position of the couple patch and the ground.

As such, as shown in FIG. 4, the power supply and short circuit terminals 370 and 380 are not implemented in the RF terminal PCB 365 but are implemented in a separate antenna PCB 360 manufactured separately, and the antenna PCB is a small size. Here, a feed terminal and a short terminal of an antenna are implemented, and a built-in antenna having a main radiation patch formed on the antenna PCB is coupled.

The couple patch 375 is located on the opposite side 390 of the feeding and shorting terminals 370 and 380 of the antenna PCB 360, and the couple patch is located in an area where the feeding and shorting terminals are opened. By overlapping with each other, the resonance by the electromagnetic coupling is realized.

Here, the size of the couple patch is also determined by the resonance frequency of the antenna to be implemented, and is connected to the ground 350 and the inductor 377 to adjust the resonance frequency according to the connection position. In addition, the antenna PCB 360 is connected to the terminal PCB 365 and the RF cable 355 to be used.

Hereinafter, a photograph of a broadband antenna structure according to an embodiment of the present invention will be illustrated, and the effects of the present invention will be described in more detail along with data on the resonance characteristics thereof.

5 is a photograph illustrating a wideband antenna implementing a couple patch on the opposite side of the feed terminal on the terminal PCB according to the present invention.

FIG. 5A shows the surface where the feed and short terminals 470 and 480 are located, and FIG. 5B illustrates the ground plane 490 on the opposite side of the feed and short terminals, and FIG. 5C shows the ground plane opposite the feed section. The photo shows a couple patch area 490 opened from the entire ground plane of the PCB. This couple patch is connected to ground by a chip inductor 377.

6 is a photograph showing a couple patch formed on the opposite side of the surface on which the feed and short terminals are located according to the present invention, and a graph showing resonance characteristics corresponding thereto.

6A is a diagram illustrating a state in which a ground plane corresponding to an area of a couple patch is grounded to the entire PCB ground plane of the terminal, and a graph of resonance characteristics thereof. As shown in Fig. 6A, resonance does not occur.

6B is a photograph showing a state in which a couple patch is opened with the entire PCB ground plane of the terminal and shorted by a chip inductor, and a graph of a corresponding resonance characteristic. It can be seen that resonance occurs as shown in FIG. 6B.

7 is a broadband antenna having a couple patch according to the present invention, illustrating a resonance characteristic according to the area of the couple patch.

It can be seen from the shift of the resonance frequency shown in FIGS. 7A and 7B that the resonance frequency moves to the high frequency region as the area of the couple patch decreases. That is, it can be seen that the resonance frequency can be easily adjusted by adjusting the area of the couple patch.

8 is a broadband antenna according to the present invention, a photograph and a graph showing a change in resonance characteristics according to the connection position of the chip inductor between the couple patch and the ground.

It can be seen that the resonance frequency is shifted according to the connection position of the chip inductance between the couple patch and the ground shown in FIGS. 8A to 8C. That is, it can be seen that the resonant frequency can be easily adjusted according to the distance according to the connection position of the feed terminal and the chip inductor.

FIG. 9 is a diagram illustrating a photograph of an antenna having a structure in which a couple patch is formed on an opposite side of a feeder of a main radiation patch in an antenna PCB according to the present invention, and a graph of resonance characteristics thereof.

9A is a photograph showing a surface on which the feeding and shorting terminals are located on the antenna PCB, and FIG. 9B is a photograph showing an antenna PCB formed by connecting a couple patch 575 to ground and an inductor 577 on the opposite side of the feeding section. 9C is a graph illustrating resonance characteristics of an antenna having a couple patch formed on the antenna PCB. As shown in FIG. 9C, it can be seen that the resonance characteristic 550 is well represented by the couple patch.

10 is a photograph illustrating a structure in which a built-in antenna is coupled onto a PCB of a terminal according to the present invention, and a graph illustrating resonance characteristics of broadband characteristics thereof.

10A is a photograph illustrating a structure in which a couple patch is formed on an antenna PCB, and FIG. 10B is a photograph showing a structure of a broadband antenna in which a built-in antenna is coupled to a terminal PCB on which a coupled patch is formed, and FIG. This is a graph showing the resonance characteristics of a broadband antenna in which a built-in antenna is mounted on a PCB having a coupled patch.

As shown in FIG. 10, it can be seen that the broadband characteristics are well represented by the double resonance caused by the main patch and the couple patch.

As described above, when the broadband antenna according to the present invention is provided, it is possible to implement a multi-or wideband antenna with a small antenna volume by solving a problem that it is difficult to secure the volume of the internal antenna while making the design of the wireless communication terminal slim and small. Done.

As another feature according to the present invention, it can be clearly seen that a wide band characteristic can be realized by forming a couple patch on the opposite side of the surface where the feed part on the PCB is located and grounding it with an inductor.

While the invention has been shown and described in connection with specific embodiments thereof, it is well known in the art that various modifications and changes can be made without departing from the spirit and scope of the invention as indicated by the claims. Anyone who owns it can easily find out.

As described above, when the broadband antenna according to the present invention is provided, it is possible to implement a multi-band antenna having a small antenna volume by solving a problem that it is difficult to secure the volume of the built-in antenna while making the design of the wireless communication terminal slim and small. do.

In addition, the resonance frequency can be easily adjusted by adjusting the area or length of the couple patch, and the resonance frequency can be easily adjusted by adjusting the connection position of the inductor between the couple patch and the ground, so that antenna characteristics of a desired band can be adjusted. It is possible to provide a wideband or multiband antenna having.

Claims (13)

A main radiation patch having a feed pin and a short pin; A printed circuit board (PCB) having a feed terminal for supplying electrical energy to the feed pin on one surface thereof, and a ground terminal for connecting the shorting pin to ground; And Broadband antenna, characterized in that provided on the opposite side to the feed terminal of the PCB is installed, having a predetermined width, a couple patch consisting of a conductor connected through the inductor and the ground. The method of claim 1, And the inductor is a chip inductor. The method according to claim 1 or 2, Resonant frequency is adjusted according to the length or area of the couple patch. The method according to claim 1 or 2, And a resonant frequency is adjusted according to the length or area of the couple patch, and the resonant frequency is adjusted according to the position of the inductor. A main radiation patch having a feed pin and a short pin; An antenna PCB having a feed terminal for supplying electrical energy to the feed pin on one surface, and a ground terminal for connecting the shorting pin to ground; And It is installed on the opposite side to the side of the feed terminal of the PCB is installed, has a predetermined width, and comprises a couple patch consisting of a conductor connected through the ground and the inductor, The antenna PCB is a broadband antenna, characterized in that connected to the terminal PCB having an RF element through the power supply. The method of claim 5, Broadband antenna, characterized in that the connection between the antenna PCB and the terminal PCB is connected by a coaxial cable. The method of claim 5, And the inductor is a chip inductor. The method of claim 5, And a resonance frequency is adjusted according to the area of the couple patch. The method of claim 5, And a resonance frequency is adjusted according to the area of the couple patch, and the resonance frequency is adjusted according to the position of the inductor. In the method for implementing the broadband characteristics of the antenna by the coupling element, In order to supply electrical energy to the main radiation patch, it is located on the opposite side of the feeder located on one side of the terminal PCB. How to implement. In the method for implementing the broadband characteristics of the antenna by the coupling element, In order to supply electric energy to the main radiation patch, it is located on the opposite side of the feeder located on one side of the antenna PCB. The antenna PCB is a method for implementing the broadband characteristics of the antenna, characterized in that the built-in antenna PCB connected to the terminal PCB having an RF element through the power supply. The method according to claim 10 or 11, wherein And a resonance frequency is changed according to the area of the couple patch. The method according to claim 10 or 11, wherein And a resonance frequency is adjusted according to the area of the couple patch, and a resonance frequency is adjusted according to the position of the inductor.

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