CN102820550B - Microwave antenna with metal elliptical surface and elliptical-like metal metamaterial as sub-reflecting surfaces - Google Patents

Abstract

The invention discloses a microwave antenna with a metal elliptical surface and an elliptical-like metal metamaterial as the sub-reflecting surfaces. The microwave antenna comprises a first sub-reflecting surface, a feed source, a second sub-reflecting surface and a transmissive metamaterial plate, wherein the first sub-reflecting surface is a rotating elliptical surface; the second sub-reflecting surface is a metamaterial panel, and is equivalent to the rotating elliptical surface in expanding electromagnetic wave; the first sub-reflecting surface is located in front of the second sub-reflecting surface, and is used for reflecting the electromagnetic wave transmitted by the feed source to the second sub-reflecting surface; and the electromagnetic wave is sent outside after being modulated by the second sub-reflecting surface and the transmissive metamaterial plate, respectively. The microwave antenna provided by the invention can widen the beam and regulate the energy distribution on the aperture surface by using the metal rotating elliptical surface and the planar metamaterial equivalent to the rotating elliptical surface as the sub-reflecting surfaces to realize multiple reflection, thereby improving the aperture efficiency of the antenna and obtaining good far-field radiation field response. In addition, the microwave antenna provided by the invention is more compact in structure, low in processing difficulty and low in cost.

Description

Subreflector is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials

Technical field

The present invention relates to the communications field, more particularly, relate to the microwave antenna that a kind of subreflector is metal ellipsoid and class spheroid shape Meta Materials.

Background technology

Microwave is the wave band in electromagnetic spectrum between ultrashort wave and infrared ray, and it belongs to the wave band of radio medium wavelength the shortest (frequency is the highest), and its frequency range is from 300MHz (wavelength 1m) to 300GHz (wavelength 0.1m).The transmitting or the reception antenna that work in the wave bands such as metric wave, decimeter wave, centimeter wave, millimeter wave are referred to as microwave antenna.In microwave antenna, applying wider has parabolic antenna, horn reflector antenna, horn antenna and lens antenna etc.

Such as, existing satellite television receiving antenna is exactly parabolic antenna, and described parabolic antenna is responsible for satellite-signal to reflex in feed and tuner.Feed be arrange at the focus place of parabolic antenna one for collecting the loudspeaker of satellite-signal, also known as corrugated horn.Its major function has two: one to be collected by the electromagnetic wave signal that antenna receives, and is transformed into signal voltage, supply high frequency head.Two is carry out polarization conversion to the electromagnetic wave received.Tuner LNB (also known as frequency demultiplier) is that the satellite-signal sent here by feed carries out frequency reducing and then signal amplification is sent to satellite receiver.

The workflow of LNB be exactly first satellite high-frequency signals is amplified to hundreds thousand of times afterwards recycle local oscillation circuit high-frequency signals is converted to intermediate frequency 950MHz-2050MHz, be beneficial to the transmission of coaxial cable and the solution mediation work of satellite receiver.Satellite receiver is that the satellite-signal transported by tuner carries out demodulation, demodulates satellite television image or digital signal and audio signal.During receiving satellite signal, parallel electromagnetic wave is converged on feed after being reflected by parabolic antenna.Usually, the feed that parabolic antenna is corresponding is a horn antenna.But because the Machining of Curved Surface difficulty of the reflecting surface of parabolic antenna is large, required precision is also high, makes trouble, and cost is higher.In addition, described existing parabolic antenna volume is comparatively large, aperture efficiency is low.

Summary of the invention

Technical problem to be solved by this invention is, for the processing of existing microwave antenna not easily, defect that cost is high, provide that a kind of to process subreflector that is simple, low cost of manufacture be the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials.

The technical solution adopted for the present invention to solve the technical problems is: a kind of subreflector is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it comprises the first subreflector, feed, second subreflector and transmission metamaterial board, described second subreflector is metamaterial panel, described metamaterial panel is provided with the centre bore being positioned at its center, described metamaterial panel comprises core layer and is arranged on the reflecting plate of core layer one side surface, described core layer comprises at least one core layer, the base material that described core layer comprises sheet and the multiple man-made microstructure be arranged on base material,

Described core layer according to refraction index profile can be divided into be distributed in around centre bore and with multiple annular regions of the concyclic heart of described centre bore, in described annular region, the refractive index at same radius place is identical, and along with the increase refractive index of radius reduces gradually in the respective region of annular region, the minimum value being in the refractive index of the annular region of inner side in adjacent two annular regions is less than the maximum of the refractive index of the annular region being in outside; Described second subreflector is the reflecting surface electromagnetic expansion being equivalent to ellipse of revolution face, and the equivalent focus of described second subreflector is between described first subreflector and the second subreflector;

Described feed is arranged on described centre bore, described first subreflector is ellipse of revolution face, described transmission metamaterial board is enclosed within described ellipse of revolution face, described first subreflector is positioned at the front of described second subreflector, and for the reflection of electromagnetic wave that will launch from described feed to described second subreflector, described electromagnetic wave is injection after described second subreflector and the modulation of transmission metamaterial board respectively.

Further, described feed phase center is placed in the far-end focus of described first subreflector.

Further, described core layer also comprises the packed layer covering man-made microstructure.

Further, the center of circle of described centre bore is the center of core layer, and the variations in refractive index scope of described multiple annular region is identical, and refractive index n 1 (r) distribution of described core layer meets following formula:

$n1\left(r\right)=n_{\max }-\frac{\mathrm{mod}(\sqrt{{(s0-s2)}^2+r^2}+\sqrt{{s1}^2+r^2}-(s1+s0-s2),\mathrm{\λ})}{2d};$

Wherein, in n1 (r) vice reflecting surface core layer, radius is the refractive index value at r place;

S0 represents the distance between the second subreflector and transmission metamaterial board;

S1 represents the distance between the near-end focus in ellipse of revolution face and the second subreflector;

S2 represents the distance between the equivalent focus of the second subreflector and transmission metamaterial board;

D is the thickness of core layer,

N _maxrepresent the refractive index maximum in core layer;

N _minrepresent the refractive index minimum value in core layer;

λ represents operation wavelength.

Further, described metamaterial panel also comprises the matching layer being arranged on core layer opposite side, to realize the index matching from air to core layer.

Further, described transmission metamaterial board is annular, described transmission metamaterial board comprises some described core lamellas, and the variations in refractive index scope of multiple annular regions of described core lamella is identical, and refractive index n 2 (r) distribution of described core layer meets following formula:

$n2\left(r\right)=n_{2\max }-\frac{\mathrm{mod}(\sqrt{{s2}^2+r^2}-s2,\mathrm{\λ})}{2d2};$

Wherein, n2 (r) represents that in core layer, radius is the refractive index value at r place;

S2 represents the distance between the equivalent focus of the second subreflector and transmission metamaterial board;

D2 is the thickness of core layer,

N _2maxrepresent the refractive index maximum in core layer;

N _2minrepresent the refractive index minimum value in core layer;

λ represents operation wavelength.

Further, described matching layer comprises multiple matching layer lamella, and each matching layer lamella has single refractive index, and the refractive index of multiple matching layer lamellas of described matching layer all meets following formula:

$n\left(i\right)={((n_{\max }+n_{\min })/2)}^{\frac{i}{m}};$

Wherein, m represents total number of plies of matching layer, and i represents the numbering of matching layer lamella, wherein, near core layer matching layer lamella be numbered m.

Further, each matching layer lamella described comprises the identical first substrate of material and second substrate, fills air between described first substrate and second substrate.

Further, multiple man-made microstructure shapes of each core layer of described core layer are identical, in described annular region, multiple man-made microstructure at same radius place have identical physical dimension, and along with the physical dimension of the increase man-made microstructure of radius reduces gradually in the respective region of annular region, adjacent two annular regions, in the annular region inside being in, the physical dimension of the man-made microstructure that physical dimension is minimum is less than the physical dimension of the man-made microstructure that physical dimension is maximum in the annular region outside being in.

Further, described man-made microstructure is the alabastrine metal micro structure of plane.

Subreflector of the present invention is the beneficial effect of the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials: the present invention utilizes a metal rotation ellipsoid and a panel metamaterial being equivalent to ellipse of revolution face to carry out multiple reflections as subreflector, wave beam is widened, Energy distribution on counterpart diametric plane regulates, thus improve the aperture efficiency of antenna, can obtain good far-field radiation field response, the structure of antenna is also compacter simultaneously; In addition, its difficulty of processing is little, and cost is low.

Accompanying drawing explanation

The structural representation of Fig. 1 to be subreflector of the present invention be microwave antenna of metal ellipsoid and class spheroid shape Meta Materials;

Fig. 2 is the perspective diagram of the metamaterial unit of a kind of form of the present invention;

Fig. 3 is the refraction index profile schematic diagram of core layer of the present invention;

Fig. 4 is the structural representation of the core layer of a kind of form of the present invention;

Fig. 5 is the structural representation of matching layer of the present invention.

Embodiment

As shown in Figures 1 to 5, the microwave antenna being metal ellipsoid and class spheroid shape Meta Materials according to subreflector of the present invention comprises the first subreflector 100, feed 1 and the second subreflector 300 and transmission metamaterial board 400.Described second subreflector 300 is metamaterial panel, it is provided with the centre bore Y of the circle being positioned at its center, described metamaterial panel comprises core layer 10 and is arranged on the reflecting plate 200 of core layer 10 1 side surface, described core layer 10 comprises at least one core layer 11, the base material 13 that described core layer 11 comprises sheet and the multiple man-made microstructure 12 be arranged on base material 13, described core layer 11 can be divided into according to refraction index profile and to be distributed in around centre bore Y and (to use H1 respectively in figure with multiple annular regions of the concyclic heart of described centre bore Y, H2, H3, H4, H5 represents).In adjacent two annular regions, the minimum value being in the refractive index of the annular region of inner side is less than the maximum of the refractive index of the annular region being in outside.It is to better describe the present invention that core layer 11 is divided into multiple annular region according to refractive index, and does not mean that core layer 11 of the present invention has this kind of practical structures.

In the present invention, described feed 1 is arranged on the centre bore Y of metamaterial panel, and is positioned on the axis of described metamaterial panel, and namely feed 1 overlaps with the axis of metamaterial panel with the line at the center of core layer 11.Described first subreflector 100 is ellipse of revolution faces, this the first subreflector 100 is positioned at the front of described metamaterial panel, described feed 1 phase center is placed in the far-end focus in described ellipse of revolution face, and the described focal axis in ellipse of revolution face overlaps with the symmetry axis of metamaterial panel.Described feed 1 and metamaterial panel all have stent support, and in figure and not shown support, it is not core of the present invention, adopts traditional supporting way.Feed 1 is preferably horn antenna in addition.Core layer 11 in figure is rounded, certainly, also can be other shape.In addition, in Fig. 3, also can not have annular region H4 and H5, H4 and H5 now can be uniform refraction index profile (i.e. the position of H4 and H5 does not arrange man-made microstructure).In addition, reflecting plate is the metallic reflection plate with smooth surface, such as, can be the copper coin of polishing, aluminium sheet or iron plate etc.

As shown in Figures 1 to 4, described core layer 10 comprises the identical and core layer 11 be parallel to each other of multiple refraction index profile.Multiple core layer 11 fits tightly, each other can be bonding by double faced adhesive tape, or is fixedly connected with by bolt etc.Core layer 11 adjacent in addition also comprises packed layer 15, and packed layer 15 can air, also can be other dielectric-slab, is preferably the plate-like piece that the material identical with base material 13 is made.The base material 13 of each core layer 11 can be divided into multiple identical metamaterial unit D, each metamaterial unit D is made up of a man-made microstructure 12, unit base material V and unit packed layer W, and each core layer 11 only has a metamaterial unit D in a thickness direction.Each metamaterial unit D can be identical square, it can be cube, may also be cuboid, the length physical dimension of each metamaterial unit D is not more than 1/5th (being generally 1/10th of incident electromagnetic wave wavelength) of incident electromagnetic wave wavelength, has continuous print electric field and/or magnetic responsiveness to make whole core layer to electromagnetic wave.Under preferable case, the cube of described metamaterial unit D to be the length of side be incident electromagnetic wave wavelength 1/10th.Certainly, the thickness of packed layer can regulate, its minimum value can down to 0, that is packed layer is not needed, in such cases, base material and man-made microstructure form metamaterial unit, namely the thickness that now thickness of metamaterial unit D equals unit base material V adds the thickness of man-made microstructure, but now, the thickness of metamaterial unit D also will meet the requirement of 1/10th wavelength, therefore, in fact, when the thickness of metamaterial unit D is selected in 1/10th wavelength, the thickness of unit base material V is larger, then the thickness of unit packed layer W is less, when certain optimum, namely be situation as shown in Figure 2, namely the thickness of unit base material V equals the thickness of unit packed layer W, and first material of unit base material V and the identical of packed layer W.

Man-made microstructure 12 of the present invention is preferably metal micro structure, and described metal micro structure is made up of one or more metal wire.Metal wire itself has certain width and thickness.Metal micro structure of the present invention preferably has the metal micro structure of isotropic electromagnetic parameter, the alabastrine metal micro structure of plane as described in Figure 2.

For the man-made microstructure with planar structure, isotropism, refer to on this two dimensional surface with arbitrary electromagnetic wave of unspecified angle incidence, namely above-mentioned man-made microstructure electric field response is on this plane all identical with magnetic responsiveness, and also dielectric constant is identical with magnetic permeability; For the man-made microstructure with three-dimensional structure, isotropism refers to that the electric field response of each above-mentioned man-made microstructure on three dimensions is all identical with magnetic responsiveness for electromagnetic wave incident in three-dimensional either direction.When man-made microstructure is 90 degree of rotational symmetry structures, namely man-made microstructure has isotropic feature.

For two-dimension plane structure, 90 degree of Rotational Symmetries refer to that it to overlap with original structure after crossing any 90-degree rotation of rotating shaft of its symmetrical centre perpendicular to this plane around one on this plane; For three-dimensional structure, if have 3 rotating shafts that are vertical between two and intersection point (intersection point is pivot) altogether, this structure is all overlapped after arbitrary rotating shaft 90-degree rotation or symmetrical with an interface with original structure with original structure, then this structure is 90 degree of rotational symmetry structures.

The alabastrine metal micro structure of plane shown in Fig. 2 is a kind of form of isotropic man-made microstructure, described alabastrine metal micro structure has the first metal wire 121 and the second metal wire 122 mutually vertically divided equally, described first metal wire 121 two ends are connected with two the first metal branch 1211 of equal length, described first metal wire 121 two ends are connected on the mid point of two the first metal branch 1211, described second metal wire 122 two ends are connected with two the second metal branch 1221 of equal length, described second metal wire 122 two ends are connected on the mid point of two the second metal branch 1221.

Known refractive index wherein μ is relative permeability, and ε is relative dielectric constant, and μ and ε is collectively referred to as electromagnetic parameter.Experiment proves, when electromagnetic wave is by refractive index dielectric material heterogeneous, and can to the large direction deviation (to the metamaterial unit deviation that refractive index is large) of refractive index.Therefore, core layer of the present invention has convergence effect to electromagnetic wave.When the material of base material and the material of packed layer are selected, the electromagnetic parameter distribution of Meta Materials inside can be obtained by the arrangement on base material of the shape of design man-made microstructure, physical dimension and/or man-made microstructure, thus design the refractive index of each metamaterial unit.First the electromagnetic parameter spatial distribution (i.e. the electromagnetic parameter of each metamaterial unit) of Meta Materials inside is calculated from the effect required for Meta Materials, the shape of the man-made microstructure in each metamaterial unit is selected according to the spatial distribution of electromagnetic parameter, physical dimension (having deposited multiple artificial microstructural data in computer in advance), the method of exhaustion can be used to the design of each metamaterial unit, such as first select the man-made microstructure that has given shape, calculate electromagnetic parameter, by the contrast that the result obtained and we are wanted, circulation repeatedly, until till the electromagnetic parameter finding us to want, if have found, the design parameter then completing man-made microstructure is selected, if do not find, then change a kind of man-made microstructure of shape, repeat circulation above, until till the electromagnetic parameter finding us to want.If still do not found, then said process also can not stop.That is only have found the man-made microstructure of the electromagnetic parameter that we need, program just can stop.Because this process is all completed by computer, therefore, seem complicated, in fact can complete soon.

In the present invention, the base material of described core layer is obtained by ceramic material, macromolecular material, ferroelectric material, ferrite material or ferromagnetic material etc.Macromolecular material is available polytetrafluoroethylene, epoxy resin, F4B composite material, FR-4 composite material etc.Such as, the electrical insulating property of polytetrafluoroethylene is very good, therefore can not produce interference to electromagnetic electric field, and have excellent chemical stability, corrosion resistance, long service life.

In the present invention, described metal micro structure is the metal wire such as copper cash or silver-colored line.The method that above-mentioned metal wire can be carved by etching, electroplating, bore quarter, photoetching, electronics quarter or ion is attached on base material.Certainly, three-dimensional laser processing technology can also be adopted.

As shown in Figure 1, be the structural representation of the metamaterial panel of first embodiment of the invention, in the present embodiment, described metamaterial panel also comprises the matching layer 20 being arranged on core layer opposite side, to realize the index matching of from air to core layer 10.We know, the refractive index between medium is larger, then, when electromagnetic wave is from a medium incident to another medium, reflect larger, and reflection is large, means the loss of energy, at this time just needs the coupling of refractive index, known refractive index wherein μ is relative permeability, and ε is relative dielectric constant, and μ and ε is collectively referred to as electromagnetic parameter.We know that the refractive index of air is 1, and therefore, design matching layer like this, the refractive index namely near the side of air and air are substantially identical, and the refractive index near the side of core layer is substantially identical with the core layer refractive index that it connects.Like this, just achieve the index matching from air to core layer, reduce reflection, namely energy loss can reduce greatly, and it is farther that such electromagnetic wave can transmit.Described second subreflector 300 is the reflectings surface electromagnetic expansion being equivalent to ellipse of revolution face, and the equivalent focus C of described second subreflector 300 is between described first subreflector 100 and the second subreflector 300.

In the present embodiment, as shown in Figures 1 and 3, the center of described centre bore Y is the center O of core layer 11, and the variations in refractive index scope of described multiple annular region is identical, and refractive index n 1 (r) distribution of described core layer 11 meets following formula:

$n1\left(r\right)=n_{\max }-\frac{\mathrm{mod}(\sqrt{{(s0-s2)}^2+r^2}+\sqrt{{s1}^2+r^2}-(s1+s0-s2),\mathrm{\λ})}{2d}---\left(1\right);$

Wherein, n1 (r) represents that in core layer, radius is the refractive index value at r place; Also be that in core layer, radius is the refractive index of the metamaterial unit of r; Radius refers to the distance of mid point to the center O (center of circle) of core layer of each unit base material V herein, and the mid point of unit base material V herein, refers to the mid point on the conplane surface of unit base material V and mid point O.

S0 represents the distance between the second subreflector and transmission metamaterial board;

S1 represents the distance between the near-end focus B in ellipse of revolution face and the second subreflector;

S2 represents the distance between the equivalent focus C of the second reflecting surface and transmission metamaterial panel, wherein, for avoiding the second subreflector that electromagnetic wave is reflected back first order subreflector again, equivalent focus C should be between near-end focus B and the second subreflector, i.e. s1+s2>s0;

D is the thickness of core layer, $d=\frac{\mathrm{\λ}}{2(n_{\max }-n_{\min })}---\left(2\right);$

N _maxrepresent the refractive index maximum in core layer 11;

N _minrepresent the refractive index minimum value in core layer 11; Described multiple annular region refractive index is all from inside to outside by n _maxbe reduced to n continuously _min.As an example, n _maxcan value 5, n _minvalue 1, that is, described multiple annular region refractive index is reduced to 1 continuously by 5 from inside to outside.

The maximum of described r has determined how many annular regions.(normally incident electromagnetic wave wavelength 1/10th) that the thickness of each core layer is normally certain, like this, when core layer shape is selected (can be square), the size of core layer just can be determined.

By formula (1), the determined core layer 10 of formula (2), can ensure that electromagnetic wave convergence that satellite etc. sends is to feed place.This by computer simulation emulation, or utilizes optical principle can obtain (namely utilizing equivalent optical path to calculate).

In the present embodiment, the thickness of core layer 11 is certain, usually in less than 1/5th of incident electromagnetic wave wavelength X, is preferably 1/10th of incident electromagnetic wave wavelength X.Like this, when designing, if have selected the number of plies of core layer 11, then the thickness d of core layer just determines, therefore, subreflector for different frequency is metal ellipsoid and the microwave antenna (wavelength is different) of class spheroid shape Meta Materials, and by formula (2), we know, by appropriate design (n _max-n _min) value, just can obtain the microwave antenna that the subreflector of frequency that arbitrarily we want is metal ellipsoid and class spheroid shape Meta Materials.Such as, C-band and Ku wave band.The frequency range of C-band is 3400MHz ~ 4200MHz.Frequency 10.7 ~ the 12.75GHz of Ku wave band, wherein can be divided into the frequency ranges such as 10.7 ~ 11.7GHz, 11.7 ~ 12.2GHz, 12.2 ~ 12.75GHz.

As shown in Figure 1, in the present embodiment, described matching layer 20 comprises multiple matching layer lamella 21, and each matching layer lamella 21 has single refractive index, and the refractive index of multiple matching layer lamellas of described matching layer all meets following formula:

$n\left(i\right)={((n_{\max }+n_{\min })/2)}^{\frac{i}{m}}---\left(3\right);$

Wherein, m represents total number of plies of matching layer, and i represents the numbering of matching layer lamella, wherein, near core layer matching layer lamella be numbered m.As can be seen from formula (3) we, the setting (total number of stories m) of matching layer and the largest refractive index n of core layer _maxwith minimum refractive index n _minthere is direct relation; As i=1, represent the refractive index of the 1st layer, because it will equal the refractive index 1 of air substantially, therefore, as long as n _maxwith n _mindetermine, then can determine total number of stories m.

Matching layer 20 can be that the multiple materials with single refractive index existed by occurring in nature are made, may also be with matching layer as shown in Figure 5, it comprises multiple matching layer lamella 21, each matching layer lamella 21 comprises the identical first substrate of material 22 and second substrate 23, fills air between described first substrate 21 and second substrate 22.By controlling the ratio of the volume of air and the volume of matching layer lamella 21, refractive index can be realized from 1 (refractive index of air) to the change of the refractive index of first substrate, thus can the refractive index of each matching layer lamella of appropriate design, realize the index matching from air to core layer.

Fig. 4 is a kind of core layer 11 of form, multiple man-made microstructure 12 shape of each core layer 11 of described core layer is identical, be the alabastrine metal micro structure of plane, and the central point of metal micro structure overlaps with the mid point of unit base material V, in described annular region, multiple man-made microstructure at same radius place have identical physical dimension, and along with the physical dimension of the increase man-made microstructure 12 of radius reduces gradually in the respective region of annular region, adjacent two annular regions, in annular region inside being in, the physical dimension of the man-made microstructure that physical dimension is minimum is less than the physical dimension of the man-made microstructure that physical dimension is maximum in the annular region outside being in.Refractive index due to each metamaterial unit reduces gradually along with the size reduction of metal micro structure, therefore man-made microstructure physical dimension is larger, then the refractive index of its correspondence is larger, therefore, the distribution of refraction index profile by formula (1) of core layer can be realized by this mode.

According to different needs (different electromagnetic waves), and different designs needs, and core layer 10 can comprise the core layer 11 as shown in Figure 4 of the different number of plies.

The structure of described transmission metamaterial board 400 and the structural similarity of described second subreflector 300, its something in common is: described transmission metamaterial board 400 is in circular, it includes described core layer and matching layer, and described core layer comprises some described core lamellas; Its difference is: the both sides of described transmission metamaterial board 400 core layer are matching layer, and refractive index n 2 (r) distribution of described core layer meets following formula:

$n2\left(r\right)=n_{\max }-\frac{\mathrm{mod}(\sqrt{{s2}^2+r^2}-s2,\mathrm{\λ})}{2d};$

Wherein, n2 (r) represents that in core layer, radius is the refractive index value at r place;

S2 represents the distance between the equivalent focus C of the second reflecting surface and transmission metamaterial panel;

D is the thickness of core layer,

N _maxrepresent the refractive index maximum in core layer;

N _minrepresent the refractive index minimum value in core layer;

λ represents operation wavelength.

Described transmission metamaterial board 400 is set on described first subreflector 100, the electromagnetic wave that described feed sends is first after described first subreflector 100 reflects, then by the first time convergence effect of the second subreflector 300 core layer, through baffle reflection, again by the second time convergence effect of core layer, finally be transferred to described transmission metamaterial board 400, modulate through described transmission metamaterial board 400, form parallel wave and launch.

In sum, the present invention utilizes a metal rotation ellipsoid and a panel metamaterial being equivalent to ellipse of revolution face to carry out multiple reflections as subreflector, wave beam is widened, Energy distribution on counterpart diametric plane regulates, thus improve the aperture efficiency of antenna, can obtain good far-field radiation field response, the structure of antenna is also compacter simultaneously; In addition, its difficulty of processing is little, and cost is low.

By reference to the accompanying drawings embodiments of the invention are described above; but the present invention is not limited to above-mentioned embodiment; above-mentioned embodiment is only schematic; instead of it is restrictive; those of ordinary skill in the art is under enlightenment of the present invention; do not departing under the ambit that present inventive concept and claim protect, also can make a lot of form, these all belong within protection of the present invention.

Claims (9)

1. a subreflector is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, comprise the first subreflector, feed, the second subreflector and transmission metamaterial board, described second subreflector is metamaterial panel, described metamaterial panel is provided with the centre bore being positioned at its center, described metamaterial panel comprises core layer and is arranged on the reflecting plate of core layer one side surface, described core layer comprises at least one core layer, the base material that described core layer comprises sheet and the multiple man-made microstructure be arranged on base material;

Described core layer according to refraction index profile can be divided into be distributed in around centre bore and with multiple annular regions of the concyclic heart of described centre bore, in described annular region, the refractive index at same radius place is identical, and along with the increase refractive index of radius reduces gradually in the respective region of annular region, the minimum value being in the refractive index of the annular region of inner side in adjacent two annular regions is less than the maximum of the refractive index of the annular region being in outside; Described second subreflector is the reflecting surface electromagnetic expansion being equivalent to ellipse of revolution face, and the equivalent focus of described second subreflector is between described first subreflector and the second subreflector;

Described feed is arranged on described centre bore, described first subreflector is ellipse of revolution face, the focal axis in described ellipse of revolution face overlaps with the symmetry axis of described metamaterial panel, described transmission metamaterial board is enclosed within described ellipse of revolution face, described first subreflector is positioned at the front of described second subreflector, and for the reflection of electromagnetic wave that will launch from described feed to described second subreflector, described electromagnetic wave is injection after described second subreflector and the modulation of transmission metamaterial board respectively;

Wherein, the center of circle of described centre bore is the center of core layer, and the variations in refractive index scope of described multiple annular region is identical, and refractive index n 1 (r) distribution of described core layer meets following formula:

$n1\left(r\right)=n_{\max }-\frac{\mathrm{mod}(\sqrt{{(s0-s2)}^2+r^2}+\sqrt{{s1}^2+r^2}-(s1+s0-s2),\mathrm{\λ})}{2d};$

Wherein, in n1 (r) vice reflecting surface core layer, radius is the refractive index value at r place;

S0 represents the distance between the second subreflector and transmission metamaterial board;

S1 represents the distance between the near-end focus in ellipse of revolution face and the second subreflector;

S2 represents the distance between the equivalent focus of the second subreflector and transmission metamaterial board;

D is the thickness of core layer, $d=\frac{\mathrm{\λ}}{2(n_{\max }-n_{\min })};$

N _maxrepresent the refractive index maximum in core layer;

N _minrepresent the refractive index minimum value in core layer;

λ represents operation wavelength.

2. subreflector according to claim 1 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described feed phase center is placed in the far-end focus of described first subreflector.

3. subreflector according to claim 2 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described core layer also comprises the packed layer covering man-made microstructure.

4. subreflector according to claim 3 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described metamaterial panel also comprises the matching layer being arranged on core layer opposite side, to realize the index matching from air to core layer.

5. subreflector according to claim 4 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described transmission metamaterial board is annular, described transmission metamaterial board comprises some core lamellas, the variations in refractive index scope of multiple annular regions of the core lamella of described transmission metamaterial board is identical, and refractive index n 2 (r) distribution of the core lamella of described transmission metamaterial board meets following formula:

$n2\left(r\right)=n_{2\max }-\frac{\mathrm{mod}(\sqrt{{s2}^2+r^2}-s2,\mathrm{\λ})}{2d2};$

Wherein, n2 (r) represents that first footpath of core lamella of transmission metamaterial board is the refractive index value at r place;

S2 represents the distance between the equivalent focus of the second subreflector and transmission metamaterial board;

D2 is the thickness of the core layer of transmission metamaterial board,

N _2maxrepresent the refractive index maximum on the core lamella of transmission metamaterial board;

N _2minrepresent the refractive index minimum value on the core lamella of transmission metamaterial board;

λ represents operation wavelength.

6. subreflector according to claim 4 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described matching layer comprises multiple matching layer lamella, each matching layer lamella has single refractive index, and the refractive index of multiple matching layer lamellas of described matching layer all meets following formula:

$n\left(i\right)={((n_{\max }+n_{\min })/2)}^{\frac{i}{m}};$

Wherein, m represents total number of plies of matching layer, and i represents the numbering of matching layer lamella, wherein, near core layer matching layer lamella be numbered m.

7. subreflector according to claim 6 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, each matching layer lamella described comprises the identical first substrate of material and second substrate, fills air between described first substrate and second substrate.

8. the subreflector according to claim 1 to 7 any one is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, multiple man-made microstructure shapes of each core layer of described core layer are identical, in described annular region, multiple man-made microstructure at same radius place have identical physical dimension, and along with the physical dimension of the increase man-made microstructure of radius reduces gradually in the respective region of annular region, adjacent two annular regions, in annular region inside being in, the physical dimension of the man-made microstructure that physical dimension is minimum is less than the physical dimension of the man-made microstructure that physical dimension is maximum in the annular region outside being in.

9. subreflector according to claim 1 is the microwave antenna of metal ellipsoid and class spheroid shape Meta Materials, it is characterized in that, described man-made microstructure is the alabastrine metal micro structure of plane.