CN102800982B - Metamaterial antenna - Google Patents

Abstract

The invention relates to a metamaterial antenna. The antenna comprises a vibrator, a first metamaterial thin-film layer, a second metamaterial thin-film layer and a reflector, wherein the vibrator is used for radiating electromagnetic waves; the first metamaterial thin-film layer is used for refracting, converging and externally propagating the electromagnetic waves radiated by the vibrator; the first metamaterial thin-film layer is connected with the reflector and forms a closed cavity with the reflector; the second metamaterial thin-film layer is arranged on the bottom layer in the reflector; and the vibrator is arranged on the second metamaterial thin-film layer and is connected with a peripheral signal transmitter by a feeder. The metamaterial antenna has the following beneficial effects: by arranging the second metamaterial thin-film layer in the reflector and arranging the first metamaterial thin-film layer at the opening of the reflector, the half-power bandwidth of the antenna is greatly reduced and the front-to-back ratio of the antenna is increased so that the directionality of the antenna is better and farther transmission of the antenna is promoted.

Description

A kind of Super-material antenna

Technical field

The present invention relates to Meta Materials field, particularly relate to a kind of Super-material antenna.

Background technology

Half-power angle, also claims 3dB beamwidth, half-power beam width, half-power bandwidth.In power radiation pattern, in a certain plane comprising main lobe greatest irradiation direction, the angle between 2 that relative greatest irradiation direction power flux-density are dropped to half place (or being less than maximum 3dB) calls half-power beam width.In field strength pattern, in a certain plane comprising main lobe greatest irradiation direction, relative greatest irradiation direction field intensity is dropped to the angle at 0.707 times of place also referred to as half-power beam width.Horizontal plane half-power beam width refers to the half-power beam width of horizontal radiation pattern, and vertical plane half-power beam width refers to the half-power beam width of elevation radiation patytern.In directional antenna, the distance of antenna propagation is determined by vertical plane half-power beam width, and namely vertical plane half-power bandwidth is less, the gain of antenna is larger, and the signal propagation distance of antenna transmission is far away, otherwise, the gain of antenna is less, and the distance that signal is propagated is also nearer.

The method improving half-power bandwidth in prior art generally has: dielectric coatings method.Dielectric coatings method adopts the form of antenna protecting equipment to be carried in the front end of aerial array, and this method can improve the gain of aerial array about 3db, makes half-power bandwidth become 36 ° and the directivity of antenna is improved.But when signal long-distance transmissions, half-power bandwidth cannot reaching our demand, sets up some base stations or relay station again to meet long distance signal transmission needs, the cost strengthened like this, also launching to signal or accepting all to make troubles.

Summary of the invention

The object of the invention is to solve the less problem of prior art antenna half-power bandwidth, a kind of Super-material antenna is provided, this antenna by arranging the second meta-material thin film layer and arrange the first meta-material thin film layer on reflector opening in reflector, greatly reduce the half-power bandwidth of antenna, improve the front and back ratio of antenna, make antenna directivity better, facilitate antenna and launch more at a distance.

In order to achieve the above object, the following technical scheme of the present invention's employing:

A kind of Super-material antenna, described antenna comprises: an oscillator, for radiated electromagnetic wave; First meta-material thin film layer, for converging the refraction of electromagnetic wave of element radiates and outwards propagating; Described antenna also comprises the second meta-material thin film layer, converges to described reflector for the part refraction of electromagnetic wave produced by oscillator; One reflector, the part reflection of electromagnetic wave for being converged by described second meta-material thin film layer is carried out refraction and is converged in described first meta-material thin film layer, and described first meta-material thin film layer is connected with reflector and forms with reflector the cavity closed; Described second meta-material thin film layer is positioned at reflector bottom; Described oscillator is placed on the second meta-material thin film layer.

Further, described second meta-material thin film layer is identical with the first meta-material thin film layer, forms by multiple metamaterial sheet.

Further, in described first meta-material thin film layer, metamaterial sheet closest to described oscillator is the first metamaterial sheet, the refractive index of described first metamaterial sheet is with its center for the rounded distribution in the center of circle, and the refraction index profile of the first metamaterial sheet is along with the Changing Pattern of radius r is as following formula:

$n\left(r\right)=n_{\max }-\frac{1}{d}\{\sqrt{{(r-\frac{1}{2}d)}^2+s^2}-s\}$

N in formula _maxrepresent the largest refractive index value in the first metamaterial sheet, d represents the thickness of the first metamaterial sheet, and s represents the distance of described oscillator to the first metamaterial sheet, and n (r) represents the refractive index value at the first metamaterial sheet inside radius r place.

Further, the structure of each metamaterial sheet described is identical, and includes substrate and cycle arrangement multiple man-made microstructure on the substrate of sheet.

Further, described reflector is electric conductor.

Further, in described first meta-material thin film layer except multiple metamaterial sheet of the first metamaterial sheet are all identical with the first metamaterial sheet.

Further, described man-made microstructure is form by least one one metal wire the planar structure or the stereochemical structure that electromagnetic field are had to response.

Further, described wire is copper wire or filamentary silver.

Further, described wire by etching, plating, bore quarters, photoetching, electronics carve or ion quarter method be attached on substrate.

Further, described man-made microstructure be the derivative shape of " work " font, " work " font, flakes or alabastrine derivative shape any one.

Further, described substrate is obtained by ceramic material, epoxy resin, polytetrafluoroethylene, FR-4 composite material or F4B composite material.

The present invention is relative to prior art, there is following beneficial effect: a kind of Super-material antenna of the present invention by arranging the second meta-material thin film layer and arrange the first meta-material thin film layer on reflector opening in reflector, greatly reduce the half-power bandwidth of antenna, improve the front and back ratio of antenna, make antenna directivity better, facilitate aerial signal and launch more at a distance.

Accompanying drawing explanation

Fig. 1 is the structural representation of a kind of Super-material antenna of the present invention;

Fig. 2 is meta-material thin film layer inner circular region of the present invention schematic diagram;

Fig. 3 is refractive index distribution schematic diagram in metamaterial sheet of the present invention;

Fig. 4 is another embodiment of the present invention structural representation;

Fig. 5 A is ' I-shaped ' man-made microstructure on meta-material thin film layer;

Fig. 5 B is ' flakes ' man-made microstructure on meta-material thin film layer;

Fig. 5 C is the man-made microstructure of the another kind ' flakes ' on meta-material thin film layer;

Fig. 5 D is another derived structure of a kind of concrete form ' flakes ' structure of man-made microstructure on meta-material thin film layer;

Fig. 6 is the arrangement schematic diagram of man-made microstructure in the substrate of meta-material thin film layer adopting I-shape construction.

Embodiment

Below in conjunction with embodiment and accompanying drawing, the present invention is described in further detail, but embodiments of the present invention are not limited thereto.

Meta Materials is a kind of is that elementary cell is also carried out spatial arrangement in a specific way, had the new material of special electromagnetic response with man-made microstructure, comprises the man-made microstructure of cycle arrangement and the substrate for man-made microstructure attachment.Man-made microstructure is form by least one one metal wire the planar structure or the stereochemical structure that electromagnetic wave are had to response, multiple man-made microstructure array arrangement on substrate, and each man-made microstructure and the shared part of the substrate accompanying by it are a metamaterial unit.Substrate can be any material different from man-made microstructure, and the superposition of this bi-material makes each metamaterial unit produce an effective dielectric constant and magnetic permeability, the electric field response of metamaterial unit that these two physical parameters are corresponding respectively and magnetic responsiveness.The feature of Meta Materials to electromagnetic response determined by the feature of man-made microstructure, and the electromagnetic response of man-made microstructure depends on the topological characteristic that its pattern wiry has and its physical dimension to a great extent.According to topological graph and the physical dimension of each man-made microstructure arranged in above-mentioned principle design Meta Materials space, just can arrange the electromagnetic parameter of every bit in Meta Materials.

Refer to Fig. 1, a kind of Super-material antenna, comprise an oscillator 10, first meta-material thin film layer 20, second meta-material thin film layer 30 and reflector 40.Described reflector 40 is a uncovered cavity, and described first meta-material thin film layer 20 forms a closed cavity with reflector 40, and the second meta-material thin film layer 30 is positioned at bottom described reflector 40, and described oscillator 10 is placed on the second meta-material thin film layer 30.

Oscillator 10 is for radiated electromagnetic wave, wherein most of electromagnetic wave directly enters in the first meta-material thin film layer 20 and carries out refraction convergence, and be converted to plane electromagnetic wave, reflect after convergence through the first meta-material thin film layer 20 again after reflector 40 reflects after also having small part electromagnetic wave to penetrate convergence by the second Meta Materials folding 30 and be converted to plane electromagnetic wave, in the present embodiment, reflector 40 is electric conductor, and described second meta-material thin film layer 30 is identical with the first meta-material thin film layer 20.

The refraction aggregation feature of the first meta-material thin film layer 20 is realized by the refraction index profile designed in it, described first meta-material thin film layer 20 is made up of multiple metamaterial sheet, and each metamaterial sheet described includes the substrate of sheet and cycle and is arranged in multiple man-made microstructure on described substrate.

For Fig. 1, the first meta-material thin film layer 20 comprises the first metamaterial sheet 201, second metamaterial sheet 202, the 3rd metamaterial sheet 203.As shown in Figure 2, the refractive index of each metamaterial sheet with its center for the rounded distribution in the center of circle.

The refraction index profile rule of described first metamaterial sheet 201 in its border circular areas is as following formula:

$n\left(r\right)=n_{\max }-\frac{1}{d}\{\sqrt{{(r-\frac{1}{2}d)}^2+s^2}-s\}$

N in its Chinese style _maxrepresent the largest refractive index value in the first metamaterial sheet, d represents the thickness of the first metamaterial sheet, and s represents the distance of described oscillator to the first metamaterial sheet, and n (r) represents the refractive index value at the first metamaterial sheet inside radius r place.

In the present embodiment, described meta-material thin film layer 20 can be designed to the refraction index profile of incident electromagnetic wave as shown in Figure 3, and wherein, AA ' is the central axis of the first meta-material thin film layer 20, according to above-mentioned formula:

$n\left(r\right)=n_{\max }-\frac{1}{d}\{\sqrt{{(r-\frac{1}{2}d)}^2+s^2}-s\}$ It is known,

N ₁> n ₂> n ₃> ... > n _p, m is greater than the natural number that 3 are less than or equal to q.

Multiple metamaterial sheet in first meta-material thin film layer 20 are all identical with the first metamaterial sheet 201, and namely the second metamaterial sheet 202 and the 3rd metamaterial sheet 203 are all identical with the first metamaterial sheet 201.

We know that refractive index formula is usually the refractive index of Meta Materials is also like this, namely the refractive index square of Meta Materials is directly proportional to the dielectric constant of material and magnetic permeability, the magnetic permeability of conventional dielectric material generally changes not quite, a constant value can be regarded as, so the refractive index of Meta Materials is only relevant to the dielectric constant of Meta Materials to a great extent, dielectric constant is larger, and the refractive index of Meta Materials is larger.

Through theoretical and actual proof, the dielectric constant of Meta Materials is relevant with the man-made microstructure shape and size in substrate and substrate, substrate adopts dielectric insulation material to make, can be ceramic material, macromolecular material, ferroelectric material, ferrite material, ferromagnetic material etc., macromolecular material can be such as, epoxy resin or polytetrafluoroethylene.Man-made microstructure is be attached to the metal wire that substrate can have response to electromagnetic wave with certain geometry, metal wire can be section is copper cash that is cylindric or flat, silver line etc., general employing copper, because copper wire is relatively cheap, the section of certain metal wire also can be other shapes, metal wire is by etching, plating, bore and carve, photoetching, electronics carve or ion quarter etc. technique be attached on substrate, whole metamaterial sheet is divided into multiple unit (man-made microstructure comprising the substrate in this unit and be attached on this cell substrate), each unit has a man-made microstructure, each unit can produce response to by electromagnetic wave wherein, thus affect electromagnetic wave transmission wherein, the size of each unit depends on the electromagnetic wave that needs respond, be generally 1/10th of the electromagnetic wavelength of required response, otherwise the arrangement that the unit comprising man-made microstructure in space forms can not be regarded as in space continuously.

When substrate is selected, by adjusting the pattern of man-made microstructure, size and the spatial distribution on substrate thereof, effective dielectric constant everywhere and equivalent permeability can be adjusted on Meta Materials and then changes Meta Materials equivalent refractive index everywhere.When man-made microstructure adopts identical geometry, the size of somewhere man-made microstructure is larger, then the effective dielectric constant at this place is larger, and refractive index is also larger.

The pattern of the man-made microstructure that the present embodiment adopts is I-shaped, as shown in Figure 5A, the distribution of man-made microstructure on substrate as shown in Figure 6, as shown in Figure 6, on substrate, the size of flakes man-made microstructure diminishes towards periphery gradually from center, heart place in a substrate, the size of alabastrine man-made microstructure is maximum, and the flakes man-made microstructure at distance center same radius place is measure-alike, therefore the effective dielectric constant of substrate is diminished to surrounding gradually by centre, middle effective dielectric constant is maximum, thus the refractive index of substrate diminishes from centre gradually to surrounding, the refractive index of mid portion is maximum.

By reference to the accompanying drawings embodiments of the invention are described above, but the present invention is not limited to above-mentioned embodiment, the pattern of man-made microstructure can be two dimension, also can be three-dimensional structure, be not limited to " work " font (as shown in Figure 5A) used in this embodiment, it can be the derived structure of " work " font, can be the orthogonal flakes in each in three dimensions bar limit shown in Fig. 5 B and the alabastrine derived structure shown in Fig. 5 C and Fig. 5 D, also can be other geometry, wherein different man-made microstructure can be that pattern is identical, but its design size is different, also can be that pattern is all not identical with design size.The quantity forming the substrate of Meta Materials can increase as required and can subtract, and the structure of each plate base can be identical, also can be different, can parallelly penetrate after metamaterial panel is propagated as long as meet the electromagnetic wave sent by antenna element.

Another embodiment of a kind of Super-material antenna of the present invention as shown in Figure 4, this antenna comprises: five oscillators 10 ', first meta-material thin film layer 20 ', second meta-material thin film layer 30 ' and reflector 40 ', described second meta-material thin film layer 30 ' is positioned at reflector 40 ' bottom, described five oscillator 10 ' laid out in parallel are in the second meta-material thin film layer 30 ', described first meta-material thin film layer 20 ' and reflector 40 ' form a closed cavity, wherein, first meta-material thin film layer 20 ' is the first meta-material thin film layer 20 laid out in parallel composition in five the first embodiments.

Five oscillators 10 ' are launched spherical electromagnetic wave major part and are directly converged by the refraction of meta-material thin film layer 20 ' and be converted to plane electromagnetic wave, then radiate, converge by the refraction of meta-material thin film layer 20 ' and be converted to plane electromagnetic wave after reflector 40 ' reflection gain after all the other small part electromagnetic waves reflect convergence by the second meta-material thin film layer 30, finally radiateing.

The structure of the first meta-material thin film layer 20 ' in the present embodiment and its inner refractive index regularity of distribution are all identical with the first meta-material thin film layer 20 in the first embodiment.

Above-described embodiment is the present invention's preferably execution mode; but embodiments of the present invention are not restricted to the described embodiments; change, the modification done under other any does not run counter to Spirit Essence of the present invention and principle, substitute, combine, simplify; all should be the substitute mode of equivalence, be included within protection scope of the present invention.

Claims (9)

1. a Super-material antenna, described antenna comprises: an oscillator, for radiated electromagnetic wave; First meta-material thin film layer, for converging the refraction of electromagnetic wave of element radiates and outwards propagating; It is characterized in that, described antenna also comprises the second meta-material thin film layer, converges to described reflector for the part refraction of electromagnetic wave produced by oscillator; One reflector, the part reflection of electromagnetic wave for being converged by described second meta-material thin film layer is carried out refraction and is converged in described first meta-material thin film layer, and described first meta-material thin film layer is connected with reflector and forms with reflector the cavity closed; Described second meta-material thin film layer is positioned at reflector bottom; Described oscillator is placed on the second meta-material thin film layer; Described second meta-material thin film layer is identical with the first meta-material thin film layer, forms by multiple metamaterial sheet.

2. a kind of Super-material antenna according to claim 1, it is characterized in that, in described first meta-material thin film layer, metamaterial sheet closest to described oscillator is the first metamaterial sheet, the refractive index of described first metamaterial sheet is with its center for the rounded distribution in the center of circle, and the refraction index profile of the first metamaterial sheet is along with the Changing Pattern of radius r is as following formula:

$n\left(r\right)=n_{\max }-\frac{1}{d}\{\sqrt{{(r-\frac{1}{2}d)}^2+s^2}-s\}$

N in formula _maxrepresent the largest refractive index value in the first metamaterial sheet, d represents the thickness of the first metamaterial sheet, and s represents the distance of described oscillator to the first metamaterial sheet, and n (r) represents the refractive index value at the first metamaterial sheet inside radius r place.

3. a kind of Super-material antenna according to claim 1, is characterized in that, the structure of each metamaterial sheet in described multiple metamaterial sheet is identical, and includes substrate and cycle arrangement multiple man-made microstructure on the substrate of sheet.

4. a kind of Super-material antenna according to claim 1, is characterized in that, described reflector is electric conductor.

5. a kind of Super-material antenna according to claim 2, is characterized in that, except multiple metamaterial sheet of the first metamaterial sheet are all identical with the first metamaterial sheet in described first meta-material thin film layer.

6. a kind of Super-material antenna according to claim 3, is characterized in that, described man-made microstructure is form by least one one metal wire the planar structure or the stereochemical structure that electromagnetic field are had to response.

7. a kind of Super-material antenna according to claim 6, is characterized in that, described wire is copper wire or filamentary silver.

8. a kind of Super-material antenna according to claim 7, is characterized in that, described wire by etching, plating, bore quarters, photoetching, electronics carve or ion quarter method be attached on substrate.

9. a kind of Super-material antenna according to claim 7, is characterized in that, described man-made microstructure be the derivative shape of " work " font, " work " font, flakes or alabastrine derivative shape any one.