KR100553269B1 - Multiband Internal Antenna - Google Patents

Abstract

The present invention relates to a multi-band internal antenna capable of transmitting and receiving triple band frequencies including a GPS band by combining a ring antenna and a modified inverted F antenna, and the present invention has an inner slot in the center and a predetermined portion. A first radiator having a ring shape having a predetermined width; A branch extending vertically vertically at a predetermined position of the first copy; A shorting pin installed on the branch; A power supply pin spaced apart from the short circuit pin by a predetermined distance; A second radiator formed by a first slot formed outside the first radiator; And a third copy formed by a second slot formed inside the first copy.

Built-in, Antenna, Multiple, Band, GPS, Ring, Inverted F Type

Description

Multi-band built-in antenna             

1 is a structural diagram of a conventional inverted F type dual band internal antenna,

2 is a structural diagram of a triple band internal antenna for accommodating a conventional GPS band;

3 is a view for explaining a form in which the built-in antenna is installed in an embodiment according to the present invention;

4 is a structural diagram of a triple band internal antenna for accommodating a GPS band according to the present invention;

5 is a graph illustrating a voltage standing wave ratio VSWR of an antenna according to the present invention.

* Explanation of symbols for main parts of the drawings

100, 101, 102: copy

103: branch

104: feed pin

105: short circuit pin

110, 111: slot

The present invention relates to an internal antenna, and more particularly, to a multi-band internal antenna capable of transmitting / receiving triple band frequencies including a GPS band by combining a ring antenna and a modified inverted F antenna.

Antennas currently used in mobile phones include monopole antennas having a λ / 4 length of a center frequency, helical antennas, and flexible antennas combining the monopole antennas and helical antennas.

On the other hand, in order to overcome the disadvantages of the antennas as described above, a built-in antenna has been proposed, the antenna having a multi-band characteristics is required because the different frequency bands for each country operator. The built-in antenna proposed by such a request includes a microstrip patch antenna using printed circuit technology, a ceramic chip antenna using a high dielectric ceramic material, and an inverted F antenna.

However, the microstrip patch antenna has a problem in that the size of the entire antenna is large, and the ceramic chip antenna has a problem in that it is weak in shock, low in gain, and expensive.

In the case of the inverted F-type antenna, the short-circuit pin is provided adjacent to the feed point, which has the advantage of reducing the size of the entire antenna. Referring to FIG. 1, the inverted F-type antenna will be described.

In the figure, a typical inverted F antenna includes a feed pin 13, a slot 12, a shorting pin 14, a first radiator 10, and a second radiator 11. Some of the signal input through the feed pin 13 flows along the current path generated in the first radiator 10 divided by the slot 12, the electromagnetic energy is radiated by the overall structure, The current is also flowed into the second radiator 11 located inside the slot 12, which has a high frequency band. Such a conventional F-type antenna has an advantage of having a dual band characteristic, but in terms of frequency response characteristics, all bands have a problem of being narrow band.

Recently, mobile phones have included a GPS function for location tracking. For this reason, there is a need for a triple band antenna capable of transmitting and receiving signals in the GPS band in addition to the dual band antenna.

In implementing the triple band antenna, there may be a method of implementing an external antenna and a method of implementing an internal antenna.

When implementing an external antenna, it is common to implement a wide band using a matching unit together with an adjacent 1900 MHz band, rather than generating a GPS band with a single independent resonant frequency. This is due to the fact that it is a helical-like structure in a limited space, basically serving 800 MHz resonance, and in addition, it is not easy to make double resonance in the near band of 1575 MHz and 1900 MHz. In the case of such a broadband frequency response characteristic, if the performance of a duplexer or a surface acoustic wave (SAW) filter is not excellent, some noise characteristics of the terminal may be deteriorated due to an increase in noise characteristics of the entire terminal due to mixing of unnecessary frequency band signals.

On the other hand, in the implementation of the built-in antenna, it is possible to implement a three-band internal antenna by combining three conventional inverted F-type antenna. However, in this case, due to the size of the antenna, there is a spatial problem exceeding a desired band in the resonant frequency band, and a characteristic problem according to the narrow band characteristic of the inverted F-type antenna.

As a conventional internal antenna that implements a triple band, there is a 'multi-frequency band antenna' of Korean Laid-Open Patent Publication No. 2001-52509.

2 is a structural diagram of the conventional triple band internal antenna, and a conventional triple band internal antenna will be described with reference to the structure.

Conventional triple band antennas are diversity antennas, consisting of a dielectric substrate such as a glass fiber circuit board having first and second ends opposing the first and second opposing surfaces. A triangular layer of copper or other conductive material is secured to the first and second substrate surfaces at opposite ends, and the underside of each triangle is adjacent to each substrate end. Each conductive layer is tapered from each end to each center on each surface. The radiating elements 40a, 40b in the figure allow the antenna to be tuned to resonate within at least three or more frequency bands. Each portion or slot 42a, 42b of each conductive layer is removed to produce an electrically conductive pattern of brainprint that emits RF energy, denoted 44a, 44b, respectively. Slots 42a and 42b in radiating elements 40a and 40b operate differently at different frequencies. At low frequencies, such as the 800 MHz band, the electrical length of the radiating elements 40a, 40b is generally the longest. In the mid range and high frequencies, such as the 1500 and 1900 MHz bands, the electrical length of the radiating element is shorter. At higher frequencies the wavelength becomes smaller, which reduces the slot's effect because energy can jump through the slot. Reference numeral 55 in the drawing is the central hole for coupling the antenna feed.

However, in order to process multiple bands with the diversity antenna, slots for processing different frequencies according to respective bands must be formed, and thus the length of the electrically conductive pattern of each brainprint of each radiating element must be long, and the different frequencies can be obtained. Since circuits must be designed according to the respective frequencies for processing the antenna, the structure of the antenna and the terminal is complicated and the size of the antenna is increased.

In addition, in order to reduce the size of the antenna, slots for processing each band and a conductive pattern thereof cannot be formed, so bandwidth is not narrowed or frequency processing according to the band is not possible, thus sufficient bandwidth cannot be generated and efficiency is low. There is a problem.

Therefore, the present invention is to solve the above problems of the prior art, by combining the ring antenna and the modified inverted F-type antenna, the multi-band internal type to operate the wavelength operating characteristics of less than 0.5λ as long as the ring antenna operates The purpose is to provide an antenna.
Other objects and advantages of the present invention can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. Also, it will be readily appreciated that the objects and advantages of the present invention may be realized by the means and combinations thereof indicated in the claims.

The present invention for achieving the above object, the first radiator having an inner slot in the center, a predetermined portion is formed in a ring shape having a predetermined width; A branch extending vertically vertically at a predetermined position of the first copy; A shorting pin installed on the branch; A power supply pin spaced apart from the short circuit pin by a predetermined distance; A second radiator formed by a first slot formed outside the first radiator; And a third copy formed by a second slot formed inside the first copy.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings, whereby those skilled in the art may easily implement the technical idea of the present invention. There will be. In addition, in describing the present invention, when it is determined that the detailed description of the known technology related to the present invention may unnecessarily obscure the gist of the present invention, the detailed description thereof will be omitted. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

3 is a view for explaining a form in which the built-in antenna is installed in an embodiment according to the present invention, in which 60 is a mobile phone rear housing, 61 is a flat copy, 62 is a support plastic frame, 63 is a mobile phone main printed circuit. Each board | substrate PCB is shown.

In the present invention, the flat plate copy may be a FR-4 substrate, which is a dielectric substrate, or a film printed circuit board (FPCB) or copper plate, which can be fixed with an adhesive tape. The planar radiator has a different antenna width and slot spacing depending on the material used. The planar radiator may calculate the antenna width and slot spacing according to the permittivity according to the planar radiator used. In the present invention, a case of using a FR-4 substrate as a dielectric substrate will be described.

내외가 최적의 범위이다. 급전핀의 한 단자는 복사체에 연결되고, 다른 하나는 메인 인쇄회로기판에 연결된다.The flat copy 61 is located between the rear housing 60 of the mobile phone and the main printed circuit board 63 and is supported by the supporting plastic frame 62. The planar copy 61 and the main printed circuit board 63 are installed in parallel with each other, and a ground plane is formed on the main printed circuit board 63. Typically, an internal antenna is provided with one or more shorting pins (not shown), which interconnect the radiator and the ground plane. Typically, the shorting pin is located a predetermined distance away from the feed pin (not shown). The reason is to widen the bandwidth. In this case, the separation distance is determined according to the frequency and the antenna material, for example

Inside and outside is the best range. One terminal of the feed pin is connected to the copy and the other to the main printed circuit board.

4 is a structural diagram of a triple band internal antenna according to the present invention, wherein the triple band internal antenna according to the present invention includes a first radiator 100 that is a ring antenna and a second radiator 101 provided on a portion of the ring antenna. And a third radiator 102, a branch 103 installed perpendicularly to an inner slot of the ring at the ring antenna, a feed pin 104 provided at a lower end of the branch 103, and the feed pin 104. Short-circuit pins 105 spaced apart from each other, a first slot 110 provided between the first and second radiators 100 and 101, the first and second radiators 100 and 102. It consists of a second slot 111 provided between.

The triple band internal antenna according to the present invention is a modification of a general ring antenna, and forms a modified inverted F antenna inside and outside about the ring antenna. This will be described in more detail with reference to FIG. 4.

In the figure, the antenna according to the present invention is a rectangular flat plate, which may take various forms. The present invention includes a first radiator 100 which is a modified ring antenna. The first radiator 100 has a ring shape having a predetermined width of only about 2/3, and a branch 103 extending perpendicular to an inner slot of the ring. ). A shorting pin 105 is installed at the free end of the branch 103. At this time, as the branch 103 is thinner and longer, the inductance component of the branch 103 increases, which is a major design parameter that reduces the overall resonance frequency of the antenna and adjusts the bandwidth. Accordingly, the operating frequency of the ring antenna can be lowered to operate at a lower place than the actual operating frequency. The ring antenna operates at about 0.5 to 0.6λ.

The first and second slots 110 and 111, respectively, are formed inside and outside the first radiator 100, which is the deformed ring antenna, and the first and second slots 110 and 111, respectively. The inner and outer sides of) are respectively formed with a second radiator 101 and a third radiator 102 operating at different frequencies to form a modified inverted F antenna. Accordingly, the second copy 101 is formed outside the first copy 100, and the third copy 102 is formed inside the first copy 100. In the drawing, the third copy 102 has a ring shape having a predetermined width as a whole by the inner slot of the ring and the circular second slot 111. The feed pin 104 is installed at a predetermined distance from the short circuit pin 105.

In the present invention, the operating frequency (1.9 GHz) of the first radiator 100, which is a ring antenna, operates at an electrical length of about 0.35 to 0.4 lambda of the center frequency. The second radiator 101 for the 800 MHz band operates at an electrical length of about 0.2λ of the center frequency of 850 MHz, and the third radiator 102 for the 1500 MHz band has an electrical length of about 0.2λ of the center frequency of 1570 MHz. It works.

Increasing the width 108 of the first radiator 100, which is the ring antenna, increases the bandwidth while lowering the operating frequency. In the present invention, the first radiator 100 is implemented to realize a multi-band in a compact structure. Width 108 is designed to be between 0.005 and 0.01 lambda of the operating frequency. The spacing 109 of the first slot 110 formed between the first radiator 100 and the second radiator 101 is designed to be about 0.01λ, and between the first radiator 100 and the third radiator 102. The spacing 107 of the formed second slot 111 is about 0.005λ, the width of the second radiator 100 is about 0.03λ, and the width 106 of the third radiator 102 is about 0.01λ. If the interval of the slot is narrowed, the operating frequency of the first radiator 100, which is a ring antenna, is further reduced, and thus may be used as a main parameter for changing each resonance frequency according to a given environment.

In the antenna according to the present invention, since the radiators operating in the respective resonant frequency bands are independently determined, the radiators may be selectively used among the radiators as necessary. For example, the GSM / DCS / US-PCS triple band recently used in North America requires very wide bandwidth characteristics in the 1800 MHz band, and according to the present invention, the length of the third radiator formed along the ring antenna and the outer slot of the ring antenna is determined. Move to DCS band resonance to cover the DCS / US-PCS band, or subtract the third copy and increase the width of the first copy so that it has broadband characteristics in the 1800 MHz band and have GSM / DCS / US-PCS triple band built-in type. The antenna can be configured.

 According to the present invention as described above, by combining the modified ring antenna and the modified inverted F antenna, there is an advantage that can exhibit sufficient characteristics without using a matching unit while minimizing the size burden according to the triple band.

FIG. 5 is a graph illustrating the voltage standing wave ratio (VSWR) of the antenna according to the present invention. When only the inverse F type antenna technology is used, a bandwidth of about 2 to 5% (VSWR 2: 1) can be expected. In FIG. 5, a bandwidth of 10% or more that can cover a commercial bandwidth can be secured.

Claims (7)

A first radiator having an inner slot in the center and having a ring portion having a predetermined width; A branch extending vertically vertically at a predetermined position of the first copy; A shorting pin installed on the branch; A power supply pin spaced apart from the short circuit pin by a predetermined distance; A second radiator formed by a first slot formed outside the first radiator; And A multiband internal antenna comprising a third radiator formed by a second slot formed inside the upper limb first radiator. The method of claim 1, And the first to third radiators are dielectric substrates. The method of claim 1, And the first to third radiators are film printed circuit boards (FPCBs) or copper plates which can be fixed with adhesive tape. The method of claim 2, The first radiator operates at an electrical length of about 0.35 to 0.4 lambda of the center frequency, and the second and third radiators operate at an electrical length of about 0.2 lambda of the center frequency, respectively. antenna. The method of claim 2, The width of the first radiator is 0.005 ~ 0.01 λ of the operating frequency, the width of the second radiator is 0.03 λ of the operating frequency, the width of the third radiator is characterized in that each determined at about 0.01 λ of the operating frequency Band internal antenna. The method of claim 2, The spacing of the first slot is 0.01λ, the spacing of the second slot is 0.005λ, characterized in that the antenna. The method of claim 1, And controlling the resonant frequency and bandwidth characteristics of the antenna by changing the inductance component of the branch by adjusting the width and length of the branch.

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