KR20080038552A - Micromini antenna using meta-material - Google Patents

Abstract

A micromini antenna using meta-material is provided to reduce the length of the antenna by using a helical radiating element twisted several times for improving an antenna gain. A micromini antenna using meta-material includes a transmission line(100) and two radiating elements(110). The transmission line constitutes a zero-order resonant circuit according to an operation principle of a metal-material transmission line and resonates in a first frequency band. Two radiating elements are connected to both ends of the transmission line respectively to resonate in a second frequency band and are helical-shaped. The transmission line has a pair of inductors(130) and a capacitor(140). The pair of inductors are installed at both connection parts of the transmission line and the radiating elements respectively. The capacitor is connected on the transmission line in series.

Description

Micromini antenna using meta-material

1 is a side view of an antenna using a conventional metamaterial.

FIG. 2 is a plan view of the antenna shown in FIG. 1. FIG.

3 is a side view of a micro-antenna using the metamaterial of the present invention.

Figure 4 is a graph showing the change in gain according to the change in the helical radiating element of the present invention.

<Explanation of symbols for the main parts of the drawings>

100: transmission line 110: helical radiating element

120: power supply unit 130: inductor

140: capacitor

The present invention relates to an antenna structure, and to an ultra-miniature antenna implemented using metamaterial transmission line theory.

In general, micro-antennas used in portable devices have a very small physical length compared to the electrical length of the antenna, and thus it is difficult to operate the antenna in a desired frequency band.

Recently, researches for implementing the Left-Handed (LH) characteristics for the miniaturization of the antenna have been actively conducted. The LH characteristic refers to the characteristic of the electric field, the magnetic field, and the propagation direction of the electromagnetic wave following the left hand law as opposed to the right hand law, and is related to the theory of artificial metamaterial.

Metamaterials are materials synthesized in an artificial manner to exhibit special electromagnetic properties that are not commonly seen in nature. In this specification, DNG (doubly negative material), negative refractive index (NRI) or LHM (left) -handed material) refers to a material or structure having a feature expressed in, for example. Metamaterials have a negative value for both their effective dielectric constant and their effective permeability under certain conditions, thus exhibiting very different electromagnetic wave propagation characteristics than ordinary materials.

In these media, the theoretical predictions of Snell's law, Doppler effect, Cerenkov radiation, etc. are reversed from those of ordinary media. In addition, in the case of electromagnetic waves traveling in such a medium, the electric field, the magnetic field, and the electron direction follow the left hand law as opposed to the right hand law in the existing medium.

The practical application of LH (left handed) propagation phenomenon in the microwave field is mainly based on the transmission line type left-handed material (LHM) structure. Since the LHM of the transmission line method is a non-resonant (or zero-order resonant) structure, it is much more advantageous in terms of bandwidth and loss than the conventional resonant structure. In addition, the structural aspect can be implemented in the form of transmission lines widely used in the microwave field, there is a more convenient advantage for practical applications in microwave circuits. Accordingly, especially in the microwave application research using the characteristics of LHM, the transmission line type LHM structure is used.

Hereinafter, the prior art will be described with reference to the drawings.

Subminiature antennas using metamaterials are disclosed in Korean Patent Applications Nos. 10-2006-0084866 and 10-2006-0091526 to the applicant.

FIG. 1 is a side view of an antenna using the metamaterial described in the above application, and FIG. 2 is a plan view of the antenna shown in FIG.

1 and 2, the antenna using the conventional metamaterial is composed of a transmission line 10 and a pair of radiating elements 11 formed at both ends of the transmission line 10. One end of the radiating element 11 of the pair of radiating elements 11 is connected to the feed section 12 so that the transmission line 10 and the helical radiating element 11 operate as a monopole antenna as a whole.

On the other hand, a pair of inductors 13 and capacitors 14 are formed on the transmission line 10, respectively. The inductor 13 is formed to be interposed between the connecting line 10 and the radiating element 11 respectively, and the capacitor 14 is formed between the both inductors 13. In more detail, the transmission line 10 is bifurcated from the point where it is connected to both inductors 13, and one capacitor 14 is formed on each of the transmission line 10 path.

In the antenna using the conventional metamaterial, an operating frequency is determined in the metamaterial transmission line 10 at the upper end, and radiation is emitted from the radiating elements 11 connected to both ends of the metamaterial transmission line 10. In this case, the two radiating elements 11 may operate as a miniature monopole antenna.

In the case of the antenna using the metamaterial, as the length of the radiating element 11 increases, the gain of the antenna is improved. Thus, in order to manufacture a smaller antenna, the length of the radiating element 11 is determined while minimizing the volume of the antenna. There is a need to develop a method that can provide more than a length.

The present invention devised to solve the above problems is an object of the present invention to provide a micro-antenna using a metamaterial that can extend the length of the radiating element which has the greatest influence on the gain of the antenna in the minimum volume.

The present invention for achieving the above object comprises a transmission line for resonating in the first frequency band by configuring a zero-order resonant circuit by the operation of the metamaterial transmission line; And two radiating elements connected to both ends of the transmission line so as to resonate in a second frequency band, and including two radiating elements formed in a helical shape.

Preferably, the micro-antenna includes a pair of inductors which are respectively formed at both connecting portions of the transmission line and the radiating element, and a capacitor formed to be connected in series on the transmission line path.

In addition, the radiating element is twisted several times to reduce the size of the antenna, the number of turns is adjusted according to the mounting space of the designed antenna.

The present invention also provides a communication device comprising the antenna described above.

In order to fully understand the present invention, the operational advantages of the present invention, and the objects achieved by the practice of the present invention, reference should be made to the accompanying drawings which illustrate preferred embodiments of the present invention and the contents described in the accompanying drawings.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings. Like reference numerals in the drawings denote like elements.

3 is a side view of a micro-antenna using the metamaterial of the present invention.

Referring to FIG. 3, the micro antenna using the metamaterial of the present invention includes a transmission line 100 and a pair of helical radiating elements 110 formed at both ends of the transmission line 100. One end of the helical radiating element 110 of the pair of helical radiating element 110 is connected to the feed unit 120, the transmission line 100 and the helical radiating element 110 to operate as a monopole antenna as a whole Can be. The transmission line 100 constitutes a first frequency band resonant circuit by configuring a zeroth order resonant circuit according to a metamaterial transmission line operation principle, and the helical radiating element 110 is disposed at both ends of the transmission line 100. It is connected and formed in a helical shape to resonate in the second frequency band.

Meanwhile, a pair of inductors 130 and capacitors 140 are formed on the transmission line 100, respectively. The inductor 130 is formed at both connecting portions of the transmission line 100 and the helical radiating element 110, respectively, and the capacitor 140 is formed between the both inductors 130. In detail, the transmission line 100 is bifurcated from the point where the two inductors 130 are connected to each other, and one capacitor 140 is formed on each of the transmission line 100 paths.

Conductive helical radiating elements 110 are formed at both ends of the transmission line 100. The helical radiating element 110 is twisted several times to further reduce the size of the antenna, the degree can be adjusted according to the mounting space of the designed antenna. In the case of the micro-antenna, since the length of the radiating element has the greatest influence on the gain of the antenna, the helical radiating element 110 may be used to manufacture a smaller antenna having a low loss in gain.

4 is a graph showing a change in gain according to the change in the helical radiating element of the present invention.

Referring to FIG. 4, since the antenna according to the present invention uses the metamaterial transmission line 100, a non-resonant (zeroth order) resonant circuit may be configured, and a resonant frequency f1 of a low frequency band in the zeroth order resonant circuit may be used. Can be formed. In addition, a resonance frequency f2 of a high frequency band may be formed by the helical radiating element 110.

The antenna gain at the resonant frequency may vary depending on the number of twists of the helical radiating element 110, and the gain of the antenna may be further improved by replacing the radiating element 110 with a helical structure. In more detail, as shown in the figure, while maintaining the electrical length of the radiating element according to the number of windings of the helical radiating element 110, the height of the radiating element can be further reduced, and the gain can be improved. That is, since the resonant frequency is determined by the metamaterial transmission line 100, the number of turns is increased, and the radiating element 110 is replaced by a helical structure while maintaining the electrical length of the radiating element. It does not have a great influence, and when helical is used, an antenna gain of equal or more can be obtained even through the radiating element 110 having a lower height, which is advantageous for miniaturization of the antenna.

On the other hand, the low frequency band resonant frequency f1 in the antenna according to the present invention is formed only by the structure of the metamaterial transmission line 100, and is not related to the length of the helical radiating element 110, so that the physical length of the antenna It is possible to implement a miniature antenna that can resonate in a desired frequency band irrespective of the frequency. Accordingly, the low frequency band resonant frequency f1 operates in the T-DMB, and the high frequency band resonant frequency f2 can be variously adjusted, such as L-band and mobile communication band, if necessary, so that the application field is very wide. At this time, since the low frequency band resonant frequency f1 is irrelevant to the size of the antenna as described above, it is easy to implement a very small antenna even at a very low operating frequency. In addition, the resonance frequency f1 of the low frequency band and the resonance frequency f2 of the high frequency band in the antenna according to the present invention are different from each other, that is, the metamaterial transmission line 100 which is a zero-order resonant circuit according to the metamaterial transmission line theory. ) And the helical radiating element 110 resonate in different ways, so that the two resonant frequencies can be adjusted independently. Moreover, in the antenna according to the present invention, since the resonant frequency f1 of the low frequency band is a zero-order resonant circuit, a multiplication frequency is not generated. Since the multiplication frequencies (2 * f1, 3 * f1 ..., etc.) of the low frequency band resonance frequency f1 are not generated, there is no problem of interference with the high frequency band resonance frequency f2.

Although the present invention has been described with reference to one embodiment shown in the drawings, this is merely exemplary, and those skilled in the art will understand that various modifications and equivalent other embodiments are possible therefrom. . Therefore, the true technical protection scope of the present invention will be defined by the technical spirit of the appended claims.

The present invention provides a micro-antenna using a metamaterial that can extend the length of a radiating element that has the greatest influence on the gain of the antenna to a maximum in a minimum volume.

Claims (4)

A transmission line configured to resonate in a first frequency band by forming a zero-order resonant circuit based on a metamaterial transmission line operation principle; And A miniature antenna using metamaterials, each of which is connected to both ends of the transmission line so as to resonate in a second frequency band and includes two radiating elements formed in a helical shape. The method of claim 1, The transmission line, A pair of inductors each formed at both connecting portions of the transmission line and the radiating element; Miniature antenna using a metamaterial comprising a capacitor formed to be connected in series on the transmission line path. The method of claim 1, The radiating element is formed by twisting a number of times in order to reduce the size of the antenna, the micro-antenna using a metamaterial that the number of turns is adjusted according to the mounting space of the designed antenna. A communication device comprising the antenna of any one of claims 1 to 3.

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