KR20140093548A - Microstrip chip antenna with top loading structure - Google Patents

Abstract

The present invention relates to a small microstrip chip antenna for electromagnetic emission of a short-range wireless communication device and relates to a small antenna structure which changes a resonant current path of a PIFA, mounted on a module for wireless communication to a non-uniform meander line and reduces a resonant frequency by attaching a top loading structure on the end. The small microstrip chip antenna for electromagnetic emission of the wireless communication device is composed of an antenna board made of substrate material and a patch forming the resonant current path by being formed on the surface of the antenna board.

Description

 BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a micro-strip antenna having a top-

The present invention relates to a small-sized microstrip chip antenna for electromagnetic wave radiation of a short-range wireless communication apparatus, and more particularly to a small-sized microstrip chip antenna for radiating a resonance current path of a planar inverted F antenna (PIFA) and a top-laid meander line radiator in which a top-loading structure is attached to an end of the meander line to lower a resonant frequency.

Planar Inverted F Antenna (PIFA) used in telecommunication equipment is a planar antenna with a square patch plate of smaller area on the ground plane of the plate as if it is turned upside down. It is a ground plane, patch, feeding point, shorting pin (Or shorting strip).

PIFA acts as a radiating element as the patch is resonated with the ground plane by current feeding. Bandwidth, gain, and resonance frequency are determined according to patch height / width / length / feed point position and short pin position. , The PIFA can be embedded in a mobile phone without protruding parts, and in order to improve the directivity, two pieces may be attached to both sides of the mobile phone, or the mobile phone may be superimposed for dual mode of two frequency bands.

In the case of a general PIFA, the size is designed to have a length of? / 4 based on the wavelength (?) Of the operating frequency. PIFA basically starts with the concept of a monopole antenna, but it differs from a monopole antenna in that the antenna radiator is horizontal and the radiator is shorted to the ground plane. The principle is that the current is supplied to the radiator through the feed point, and the current flowing through the radiator returns to the ground plane through the shorting pin while resonating.

1 is a view of PIFA having a general? / 4 resonance length. It is possible to confirm the structure of the antenna board 11, patch antenna feed point 13, ground plane connection point 14 and hole 15 constituting the antenna 10 in a basic form in which no molding is performed Due to its large volume, it is not suitable for mounting on Zigbee or Bluetooth communication module. Fig. 2 shows the frequency response characteristics of the antenna of Fig.

As shown in FIG. 2, the general PIFA is not suitable for mounting in a radio communication apparatus requiring a small antenna of less than? / 4 in the 2.4-2.5 GHz band.

In order to solve this problem, a miniering technique has been introduced in which a line is bent and designed to give a condition capable of resonating in a frequency band that can rise in a space smaller than the length of? / 4.

Meandering is a method of reducing the physical size of the antenna by increasing the electrical distance of the antenna. If the distance between the bent lines is too narrow, parasitic capacitance coupling between the patches, which interferes with the inductive capacity of the line, Or the bandwidth may be reduced.

FIG. 3 is a view showing the antenna of FIG. 1 changed into a meander line shape. By designing the antenna board 21, patch antenna feed point 23, ground plane connection point 24 and hole 25 constituting the antenna 20 as a meander line including the structure as it is, As shown in FIG. 4, since the frequency response characteristic is 2.55 GHz, the size has to be increased to be larger than the present one in order to design a frequency of 2.45 GHz required by a communication device.

SUMMARY OF THE INVENTION The present invention has been proposed in order to solve the above-mentioned problems, and it is an object of the present invention to provide a designing method of maintaining a frequency by preventing a rise in frequency while reducing antenna size compared to a conventional PIFA size by top- , A PIFA antenna with a λ / 4 length, which is widely used in commercial communication devices together with a monopole antenna, can be manufactured at 2.4 to 2.5 GHz, while maintaining the bandwidth, gain and efficiency, And it is an object of the present invention to provide a small antenna for a line radiator.

The small-sized antenna of the top-rolled meander line radiator according to the present invention is a small-sized microstrip chip antenna for radiating electromagnetic waves of a wireless communication device, comprising: an antenna board made of a substrate material; Wherein the patch comprises a non-uniform meander line to reduce the parasitic capacitance on the adjacent line and thereby the possibility of additional frequency drift, and the meander line, And a top loading structure is attached to the end of the resonator to lower the resonance frequency.

The small-sized antenna of the top-laid meander line radiator according to the present invention can be obtained by first downsizing a conventional PIFA having a length of? / 4 using a meander type line and then using a top- It is possible to obtain the gain, bandwidth and efficiency suitable for the communication device in the size of the antenna of? / 8 size.

1 shows a PIFA structure having a typical? / 4 length,
2 shows the frequency response characteristics of a PIFA structure having a general length of? / 4,
FIG. 3 shows a PIFA structure miniaturized to a length of? / 8 through a meander line,
4 shows the frequency response characteristics of a PIFA structure miniaturized to a length of? / 8 through a meander line,
FIG. 5 shows a modified PIFA antenna of a meander line including a top-downing structure that is miniaturized to a lambda / 8 length according to the present invention,
FIG. 6 is a schematic view schematically showing patches formed on the upper and lower surfaces of FIG. 5,
FIG. 7 is a graph showing the frequency response characteristics of a meander line PIFA antenna including a top-downing structure of a lambda / 8 length according to the present invention,
8 is a graph showing a current distribution of a meander line PIFA structure including a top-downing structure that is miniaturized to a lambda / 8 length according to the present invention,
FIG. 9 is a graph showing an electric field vector distribution of a meander line modified PIFA structure including a top-downing structure that is miniaturized to a lambda / 8 length of the present invention,
10 is a microwave radiation pattern of a meander line modified PIFA structure including a top-downing structure that is miniaturized to a lambda / 8 length of the present invention.

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

INDUSTRIAL APPLICABILITY The present invention is applied to a small-sized microstrip chip antenna for radiating electromagnetic waves of a wireless communication device, so that miniaturization and performance maintenance of the antenna are the main object.

For this purpose, a meander type which bends the line to give a condition that resonates in the above-mentioned frequency that can rise in a space smaller than the length of? / 4 is selected.

5 and 6, a small antenna of a meander line radiator having a top-loading structure according to the present invention includes an antenna board 31 composed of a substrate material, And a patch 32 formed on the surface and forming a path of the resonance current.

The patch 32 formed on the upper surface of the antenna board 31 includes the rectilinear section 32a in which a straight line having a predetermined width is changed in direction at 90 degrees for different lengths and the rectilinear section 32a forming the end of the rectilinear section 32a, And a patch 32 formed on the lower surface of the antenna board 31 forms an antenna feed point 33 and a ground plane connection point 34 .

At this time, a hole 35 is provided at the tip of the antenna feed point 33 and the straight portion 32a so as to be electrically connected to each other, and the conductance value L is determined by the size of the hole 35 .

In the non-uniform meander line, the capacitance value C is determined by the length of the rectilinear section 32a and the top-loading structure formed in the spatial section 32b.

The top-downing structure means attaching top loading to one side of the surface of the space, and is a well-known technology used in the field of telecommunication in the past. And the description of the top-downing structure is replaced by the current distribution shown in Fig. 8 and the electric field vector distribution shown in Fig.

In the conventional uniform type line, the pattern formed by the patch is uniform, and parasitic capacitance between the adjacent lines and the possibility of additional frequency movement are generated. In order to prevent this, the non-uniform meander line is adopted.

In order to lower the operating frequency, a top loading (40) structure is formed at the end of the meander line to maintain the performance of the λ / 4 length PIFA. To reduce the occupied area of the optical fiber to less than λ / 4.

That is, in the conventional meandering line antenna, if the interval between the bent lines is too narrow, parasitic capacitance coupling between the patches that interfere with the inductive capacity of the line is generated, and the efficiency is decreased or the bandwidth is reduced. , A top-loading structure was attached at the end of the meander line to increase the capacitance component that does not impede the inductive capacity of the line.

Therefore, it is possible to maintain the performance of the? / 4 length PIFA while reducing the overall length to? / 8 by using the meander line and the top-loading structure.

At this time, as shown in FIG. 7, when the top-loading structure is attached to the meander type PIFA, it can be confirmed that the resonance frequency is lowered by about 100 MHz as compared with the result of molding only in the conventional meander type.

As described above, although the length of the antenna 30 is reduced to half by the top-downing structure of the present invention, current / electric field characteristics and antenna radiation pattern similar to those of the conventional PIFA are exhibited.

8 and 9 are a current distribution and an electric field vector distribution of a meander line PIFA structure including a top-loading structure according to the present invention. FIG. 10 shows that an omni-directional characteristic appears in an antenna radiation pattern like a basic PIFA Able to know. At this time, the gain was more than 2dBi and the efficiency was more than 80%.

It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the spirit or scope of the invention as defined in the appended claims. will be.

10, 20, 30: antennas 11, 21, 31: antenna board
12, 22, 32: Patch 13, 23, 33: Antenna feed point
14,24,34: ground plane connection point 15,25,35: hole
32a: straight line portion 32b:
40: Top rowing

Claims (4)

A small microstrip chip antenna for electromagnetic wave radiation of a wireless communication device,
An antenna board 31 made of a substrate material and a patch 32 formed on the surface of the antenna board 31 and forming a path of a resonance current,
The patch 32 may be constructed with a non-uniform meander line to reduce parasitic capacitance on adjacent lines and thus additional frequency drift, and a top loading structure at the end of the meander line 40) is attached to lower the resonance frequency of the meander line radiator.
The method according to claim 1,
The patch 32 formed on the upper surface of the antenna board 31 includes the rectilinear section 32a in which a straight line having a predetermined width is changed in direction at 90 degrees for different lengths and the rectilinear section 32a forming the end of the rectilinear section 32a, Forming a non-uniform meander line including a space portion (32b) to which a diving structure is attached,
Wherein the patch 32 formed on the lower surface of the antenna board 31 comprises an antenna feed point 33 and a ground plane connection point 34. The meander line radiator of claim 1,
3. The method of claim 2,
The antenna feed point 33 and the straight line portion 32a are provided with a hole 35 so as to be electrically connected to each other,
And the conductance value (L) is determined by the size of the hole (35).
3. The method of claim 2,
Wherein the non-uniform meander line has a capacitance value (C) determined by the length of the rectilinear section (32a) and the top-loading structure formed in the spatial section (32b) Small antenna of radiator.

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