CN102480064B - Feed-forward type satellite television antenna and satellite television receiving system thereof - Google Patents

Abstract

The invention discloses a feed-forward type satellite television antenna, which comprises a metamaterial panel arranged behind a feed source. The metamaterial panel consists of a core layer and a reflector arranged on the surface of one side of the core layer, the core layer comprises at least one core layer slice layer, each core layer slice layer comprises a flaky base material and a plurality of artificial micro-structures, refractive indexes of each core layer slice layer are circularly distributed, and the refractive indexes of positions, with identical radiuses, of each core layer slice layer are identical, and are gradually reduced along with increase of the radiuses. The flaky metamaterial panel replaces a traditional parabolic antenna, and accordingly the feed-forward type satellite television antenna is easy in manufacture and processing and low in cost. In addition, the invention provides a satellite television receiving system comprising the feed-forward type satellite television antenna.

Description

A kind of feed forward type satellite tv antenna and satellite television receiving system thereof

Technical field

The present invention relates to the communications field, more particularly, relate to a kind of feed forward type satellite tv antenna and satellite television receiving system thereof.

Background technology

The satellite earth receiving station that traditional satellite television receiving system is comprised of parabolic antenna, feed, tuner, satellite receiver.Parabolic antenna is responsible for satellite-signal is reflexed to feed and the tuner that is positioned at the focus place.Feed is loudspeaker that are used for collecting satellite-signal that arrange at the focus place of parabolic antenna, claims again corrugated horn.Its major function has two: the one, the electromagnetic wave signal of antenna reception is collected, and be transformed into signal voltage, the supply high frequency head.The 2nd, the electromagnetic wave that receives is carried out polarization conversion.Tuner LNB (also claiming frequency demultiplier) carries out frequency reducing and signal with the satellite-signal that feed is sent here to amplify and then be sent to satellite receiver.Generally can be divided into C-band frequency LNB (3.7GHz-4.2GHz, 18-21V) and Ku audio range frequency LNB (10.7GHz-12.75GHz, 12-14V).The workflow of LNB is exactly to recycle local oscillation circuit after first the satellite high-frequency signals being amplified to hundreds thousand of times high-frequency signals is converted to intermediate frequency 950MHz-2050MHz, is beneficial to the transmission of coaxial cable and the solution mediation work of satellite receiver.Satellite receiver is that the satellite-signal that tuner transports is carried out demodulation, demodulates satellite television image or digital signal and audio signal.

During receiving satellite signal, parallel electromagnetic wave converges on the feed after reflecting 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, therefore, make trouble, and cost is higher.

Summary of the invention

Technical problem to be solved by this invention is for the defective that existing satellite tv antenna processing is difficult for, cost is high, to provide a kind of feed forward type satellite tv antenna simple, low cost of manufacture of processing.

The technical solution adopted for the present invention to solve the technical problems is: a kind of feed forward type satellite tv antenna, described feed forward type satellite tv antenna comprises the super material panel that is arranged on the feed rear, described super material 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 lamella, described core layer lamella comprises the base material of sheet and is arranged on a plurality of artificial micro-structural on the base material, the rounded distribution of the refractive index of described core layer lamella, and the refractive index at same radius place is identical, along with the increase refractive index of radius reduces gradually.

Further, described core layer lamella also comprises the packed layer that covers artificial micro-structural.

Further, described core layer comprises the core layer lamella that a plurality of refraction index profile are identical and be parallel to each other.

Further, described super material panel also comprises the matching layer that is arranged on the core layer opposite side, to realize the index matching from the air to the core layer.

Further, the rounded distribution take its center as the center of circle of the refractive index of described core layer lamella, the refractive index n of described core layer lamella (r) distributes and satisfies following formula:

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

Wherein, radius is the refractive index value at r place on n (r) the expression core layer lamella;

L is the distance that feed arrives the matching layer close with it, or l is the distance that feed arrives core layer;

D is the thickness of core layer, $d=\frac{\sqrt{l^2+R^2}-l}{2(n_{\max }-n_{\min })};$

R represents maximum radius;

n _MaxRefractive index maximum on the expression core layer lamella;

n _MinRefractive index minimum value on the expression core layer lamella.

Further, described matching layer comprises a plurality of matching layer lamellas, and each matching layer lamella has single refractive index, and the refractive index of a plurality of matching layer lamellas of described matching layer all satisfies 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, and near the m that is numbered of the matching layer lamella of core layer.

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

Further, a plurality of artificial micro-structural shape of each core layer lamella of described core layer is identical, and a plurality of artificial micro-structural at same radius place has identical physical dimension, and along with the physical dimension of the artificial micro-structural of increase of radius reduces gradually.

Further, described artificial micro-structural is the alabastrine metal micro structure in plane.

According to feed forward type satellite tv antenna of the present invention, replaced traditional parabolic antenna by the super material panel of sheet, to make processing and be more prone to, cost is cheaper.

The present invention also provides a kind of satellite television receiving system, comprises feed, tuner and satellite receiver, and described satellite television receiving system also comprises above-mentioned feed forward type satellite tv antenna, and described feed forward type satellite tv antenna is arranged on the rear of feed.

Description of drawings

Fig. 1 is the structural representation of feed forward type satellite tv antenna of the present invention;

Fig. 2 is the perspective diagram of the super material cell of a kind of form of the present invention;

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

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

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

Embodiment

Extremely shown in Figure 5 such as Fig. 1, the feed forward type satellite tv antenna comprises the super material panel 100 that is arranged on feed 1 rear according to the present invention, described super material panel 100 comprises core layer 10 and is arranged on reflecting plate 200 on core layer one side surface, described core layer 10 comprises at least one core layer lamella 11, described core layer lamella comprises the base material 13 of sheet and is arranged on a plurality of artificial micro-structural 12 on the base material 13, the rounded distribution take its center as the center of circle of the refractive index of described core layer lamella 11, the refractive index at same radius place is identical, and along with the increase refractive index of radius reduces gradually.Among the present invention, feed 1 is arranged on the axis of super material panel, and namely feed overlaps with the axis of super material panel with the line at the center of core layer lamella 11.Feed 1 all has stent support with super material panel 100, and among the figure and not shown support, it is not core of the present invention, adopts traditional supporting way to get final product.Feed is preferably horn antenna in addition.Core layer lamella 11 among the figure is square, and certainly, also can be other shape, and is for example cylindrical.In addition, reflecting plate is the metallic reflection plate with smooth surface, such as copper coin, aluminium sheet or the iron plate etc. that can be polishing.

As shown in Figures 1 to 4, described core layer 10 comprises the core layer lamella 11 that a plurality of refraction index profile are identical and be parallel to each other.A plurality of core layer lamellas 11 fit tightly, each other can be bonding by double faced adhesive tape, perhaps be fixedly connected with by bolt etc.Adjacent core layer lamella 11 also comprises packed layer 15 in addition, and packed layer 15 can air, can be other dielectric-slab also, is preferably the plate-like piece that the material identical with base material 13 made.The base material 13 of each core layer lamella 11 can be divided into a plurality of identical super material cell D, each super material cell D is made of an artificial micro-structural 12, unit base material V and unit packed layer W, and each core layer lamella 11 only has a super material cell D at thickness direction.Each super material cell D can be identical square, it can be cube, also cuboid, the length physical dimension of each super material cell D is not more than 1/5th (are generally incident electromagnetic wave wavelength 1/10th) of incident electromagnetic wave wavelength, so that whole core layer has continuous electric field and/or magnetic responsiveness to electromagnetic wave.Under the preferable case, described super material cell D is that the length of side is the cube of incident electromagnetic wave wavelength 1/10th.Certainly, the thickness of packed layer can be regulated, its minimum value can be down to 0, that is to say does not need packed layer, in such cases, base material and artificial micro-structural form super material cell, namely this moment super material cell D the thickness thickness that equals unit base material V add the thickness of artificial micro-structural, but this moment, the thickness of super material cell D also will satisfy the requirement of 1/10th wavelength, therefore, in fact, thickness at super material cell D is selected in the situation of 1/10th wavelength, and the thickness of unit base material V is larger, and then the thickness of unit packed layer W is less, certainly in the optimum situation, 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 the material of first unit base material V and packed layer W's is identical.

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

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

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

The alabastrine metal micro structure in plane shown in Figure 2 is a kind of form of isotropic artificial micro-structural, described alabastrine metal micro structure has the first metal wire 121 and the second metal wire 122 of mutually vertically dividing equally, described the first metal wire 121 two ends are connected with two the first metal branches 1211 of equal length, described the first metal wire 121 two ends are connected on the mid point of two the first metal branches 1211, described the second metal wire 122 two ends are connected with two the second metal branches 1221 of equal length, and described the second metal wire 122 two ends are connected on the mid point of two the second metal branches 1221.

Known refractive index

, wherein μ is relative permeability, and ε is relative dielectric constant, and μ and ε are collectively referred to as electromagnetic parameter.Experiment showed, when electromagnetic wave passes through refractive index dielectric material heterogeneous, can be to the large direction deviation of refractive index (to the large super material cell deviation of refractive index).Therefore, core layer of the present invention has the effect of converging to electromagnetic wave, the electromagnetic wave that satellite sends is at first by converging effect the first time of core layer, through baffle reflection, again by converging effect the second time of core layer, therefore, the refraction index profile of appropriate design core layer, can be so that the electromagnetic wave that satellite sends be successively through converging for the first time, after baffle reflection and second converges, can converging on the feed.In the selected situation of the material of the material of base material and packed layer, the electromagnetic parameter that can obtain super material internal by shape, physical dimension and/or artificial micro-structural the arranging on base material of designing artificial micro-structural distributes, thereby designs the refractive index of each super material cell.At first calculate the electromagnetic parameter spatial distribution (being the electromagnetic parameter of each super material cell) of excess of export material internal from the needed effect of super material, select the shape of the artificial micro-structural on each super material cell according to the spatial distribution of electromagnetic parameter, physical dimension (having deposited in advance multiple artificial micro-structural data in the computer), design to each super material cell can be used the method for exhaustion, for example select first the artificial micro-structural with given shape, calculate electromagnetic parameter, with the result who obtains and the contrast that we want, circulation repeatedly, till the electromagnetic parameter that finds us to want, if found, then finished the design parameter of artificial micro-structural and selected; If do not find, then change a kind of artificial micro-structural of shape, the circulation above repeating is till the electromagnetic parameter that finds us to want.If still do not find, then said process can not stop yet.That is to say the artificial micro-structural of the electromagnetic parameter that has only found our needs, program just can stop.Because this process is all finished by computer, therefore, seem complicated, in fact can finish soon.

Among the present invention, the base material of described core layer is made 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.For example, the electrical insulating property of polytetrafluoroethylene is very good, therefore can not produce electromagnetic electric field and disturb, and have good chemical stability, corrosion resistance, long service life.

Among the present invention, described metal micro structure is the metal wires such as copper cash or silver-colored line.Above-mentioned metal wire can be attached on the base material by etching, plating, brill quarter, photoetching, electronics is carved or ion is carved method.Certainly, also can adopt three-dimensional laser processing technology.

As shown in Figure 1, be the structural representation of the super material panel of first embodiment of the invention, in the present embodiment, described super material panel also comprises the matching layer 20 that is arranged on the core layer opposite side, to realize from the air to the core layer 10 index matching.We know that the refractive index between the medium differs larger, when then electromagnetic wave incides another medium from a medium, reflect greatlyr, 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 are collectively referred to as electromagnetic parameter.We know that the refractive index of air is 1, therefore, design like this matching layer, and namely refractive index and the air of a side of close air are basic identical, and the core layer lamella refractive index that the refractive index of a side of close core layer is joined with it is basic identical.Like this, just realized the index matching from the air to the core layer, reduced reflection, i.e. energy loss can reduce greatly, like this electromagnetic wave can transmit farther.

In the present embodiment, such as Fig. 1 and shown in Figure 3, the refractive index of described core layer lamella 11 is take the rounded distribution as the center of circle of its center O, and the refractive index n of described core layer lamella 11 (r) distributes and satisfies following formula:

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

Wherein, radius is the refractive index value at r place on n (r) the expression core layer lamella; Also be that radius is the refractive index of the super material cell D of r on the core layer lamella; The radius mid point that refers to each unit base material V is to the distance of the center O (center of circle) of core layer lamella herein, and the mid point of unit base material V herein refers to the mid point on unit base material V and the conplane surface of mid point O.

L is that feed 1 is to the distance of the matching layer 20 close with it;

D is the thickness of core layer, $d=\frac{\sqrt{l^2+R^2}-l}{2(n_{\max }-n_{\min })}---\left(2\right);$

R represents maximum radius;

n _MaxRefractive index maximum on the expression core layer lamella 11;

n _MinRefractive index minimum value on the expression core layer lamella 11;

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

In the present embodiment, the thickness of core layer lamella 11 is certain, usually below 1/5th of incident electromagnetic wave wavelength X, and preferably 1/10th of the incident electromagnetic wave wavelength X.Like this, when design, if selected the number of plies of core layer lamella 11, then the thickness d of core layer has just been determined, therefore, and for the feed forward type satellite tv antenna (wavelength is different) of different frequency, we know by formula (2), by appropriate design (n _Max-n _Min) value, just can obtain arbitrarily the feed forward type satellite tv antenna of the frequency that we want.For example, 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 a plurality of matching layer lamellas 21, and each matching layer lamella 21 has single refractive index, and the refractive index of a plurality of matching layer lamellas of described matching layer all satisfies following formula:

$n\left(i\right)={((n_{\max }+n_{\min })/2)}^{\frac{i}{m}}---\left(4\right);$

Wherein, m represents total number of plies of matching layer, and i represents the numbering of matching layer lamella, wherein, and near the m that is numbered of the matching layer lamella of core layer.We can find out from formula (4), the largest refractive index n of the setting of matching layer (total number of stories m) and core layer _MaxWith minimum refractive index n _MinDirect relation is arranged; When i=1, represent the 1st layer refractive index, 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 to be made by a plurality of materials with single refractive index that occurring in nature exists, also use matching layer as shown in Figure 5, it comprises a plurality of matching layer lamellas 21, each matching layer lamella 21 comprises material identical first substrate 22 and second substrate 23, fills air between described first substrate 21 and the second substrate 22.The ratio of the volume by the control volume of air and matching layer lamella 21, can realize the variation of refractive index from 1 (refractive index of air) to the refractive index of first substrate, thereby refractive index that can each matching layer lamella of appropriate design realizes the index matching from the air to the core layer.

Fig. 4 is a kind of core layer lamella 11 of form, a plurality of artificial micro-structural 12 shapes of each core layer lamella 11 of described core layer are identical, be the alabastrine metal micro structure in plane, and the central point of metal micro structure overlaps with the mid point of unit base material V, the a plurality of artificial micro-structural at same radius place has identical physical dimension, and along with the physical dimension of the artificial micro-structural 12 of the increase of radius reduces gradually.Because the refractive index of each super material cell is to reduce gradually along with the size reduction of metal micro structure, therefore artificial micro-structural physical dimension is larger, then its corresponding refractive index is larger, therefore, can realize the by formula distribution of (1) of refraction index profile of core layer lamella by this mode.

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

The present invention also has the second embodiment, and the difference of the second embodiment and the first embodiment is that the l in refractive index n (r) distribution formula of core layer lamella 11 represents that feed is to the distance (l represents that feed arrives the distance of the matching layer close with it among the first embodiment) of core layer.

In addition, the present invention also provides the present invention that a kind of satellite television receiving system also is provided, comprise feed, tuner and satellite receiver, described satellite television receiving system also comprises above-mentioned feed forward type satellite tv antenna, and described feed forward type satellite tv antenna is arranged on the rear of feed.

Feed, tuner and satellite receiver are existing technology, no longer state herein.

The above is described embodiments of the invention by reference to the accompanying drawings; but the present invention is not limited to above-mentioned embodiment; above-mentioned embodiment only is schematic; rather than restrictive; those of ordinary skill in the art is under enlightenment of the present invention; not breaking away from the scope situation that aim of the present invention and claim protect, also can make a lot of forms, these all belong within the protection of the present invention.

Claims (9)

1. feed forward type satellite tv antenna, it is characterized in that, described feed forward type satellite tv antenna comprises the super material panel that is arranged on the feed rear, described super material 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 lamella, described core layer lamella comprises the base material of sheet and is arranged on a plurality of artificial micro-structural on the base material, the rounded distribution of the refractive index of described core layer lamella, and the refractive index at same radius place is identical, along with the increase refractive index of radius reduces gradually, the refractive index n of described core layer lamella (r) distributes and satisfies following formula:

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

Wherein, radius is the refractive index value at r place on n (r) the expression core layer lamella;

L is the distance that feed arrives the matching layer close with it, or l is the distance that feed arrives core layer;

D is the thickness of core layer, $d=\frac{\sqrt{l^2+R^2}-l}{2(n_{\max }-n_{\min })};$

R represents maximum radius;

n _MaxRefractive index maximum on the expression core layer lamella;

n _MinRefractive index minimum value on the expression core layer lamella.

2. feed forward type satellite tv antenna according to claim 1 is characterized in that, described core layer lamella also comprises the packed layer that covers artificial micro-structural.

3. feed forward type satellite tv antenna according to claim 2 is characterized in that, described core layer comprises the core layer lamella that a plurality of refraction index profile are identical and be parallel to each other.

4. feed forward type satellite tv antenna according to claim 3 is characterized in that, described super material panel also comprises the matching layer that is arranged on the core layer opposite side, to realize the index matching from the air to the core layer.

5. feed forward type satellite tv antenna according to claim 4, it is characterized in that, described matching layer comprises a plurality of matching layer lamellas, and described each matching layer lamella has single refractive index, and the refractive index of a plurality of matching layer lamellas of described matching layer all satisfies 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, and near the m that is numbered of the matching layer lamella of core layer.

6. feed forward type satellite tv antenna according to claim 5 is characterized in that, described each matching layer lamella comprises first substrate and the second substrate that material is identical, fills air between described first substrate and the second substrate.

7. according to claim 2 to the described feed forward type satellite tv antenna of 6 any one, it is characterized in that, the a plurality of artificial micro-structural shape of each core layer lamella of described core layer is identical, the a plurality of artificial micro-structural at same radius place has identical physical dimension, and along with the physical dimension of the artificial micro-structural of increase of radius reduces gradually.

8. feed forward type satellite tv antenna according to claim 1 is characterized in that, described artificial micro-structural is the alabastrine metal micro structure in plane.

9. satellite television receiving system, comprise feed, tuner and satellite receiver, it is characterized in that described satellite television receiving system comprises that also described feed forward type satellite tv antenna is arranged on the rear of feed such as the described feed forward type satellite tv antenna of claim 1 to 8 any one.

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