JP5701643B2 - Dual polarization antenna - Google Patents

Description

  The present invention relates to a dual-polarized antenna that forms a bidirectional radio transmission path by sharing linearly polarized waves that are orthogonal to each other.

  In satellite communication earth station devices that form radio transmission paths using linearly polarized waves separately for transmission and reception, such as VSAT (Very Small Aperture Terminal), SNG (Satellite News Gathering), ESV (Earth Station on Board Vessels), Switching between vertical polarization and horizontal polarization according to transmission / reception is performed, and a polarization sharing antenna that can share these vertical polarization and horizontal polarization with one antenna is applied.

FIG. 5 is a diagram illustrating a configuration example of the polarization sharing antenna.
FIG. 6 is a diagram showing a detailed configuration of a slot and a feed system in a conventional dual-polarization antenna.
As shown in FIG. 6, the bottom of the flat case 22 having a substantially rectangular top as shown in FIG. The ground conductor 31L, the dielectric 32L, the power supply board 33L, the dielectric 32M, the ground conductor 31M, the dielectric 32U, the power supply board 33U, the dielectric 32T, and the ground conductor 31T are stacked and stored in the direction from the opening to the opening. .

In the ground conductor 31T, upper layer slots 31TH-ij (i = 1 to 32, j = 1 to 24) are formed as square through holes arranged at regular intervals in a lattice of 32 columns × 24 rows.
On the power supply substrate 33U, rectangular upper layer elements 33UE-ij (i = 1 to 32, j = 1 to 24) are formed at portions respectively facing the upper layer slots 31TH-ij through the dielectric 32T. Of the four sides of the upper layer element 33UE-ij, as feed lines individually and vertically connected to the center of the common side (hereinafter referred to as “first side”) in the row direction of the lattice described above A triplate line 33UF is formed.

  On the power supply substrate 33L, rectangular lower layer elements 33LE-ij (i = 1 to 32, respectively) are disposed at portions facing the above-described upper layer element 33UE-ij via the dielectric 32M, the ground conductor 31M, and the dielectric 32U. j = 1 to 24), and among these four sides of the lower layer element 33LE-ij, a common side (hereinafter referred to as a “second side”) orthogonal to the above-described “first side”. The triplate line 33LF is formed as a feed line that is individually vertically connected to the center of the).

  The ground conductor 31M is disposed at each portion sandwiched between the above-described upper layer element 33UE-ij and the lower layer element 33LE-ij, and individually faces the lower layer element 33LE-ij (upper layer element 33UE-ij). Lower layer slots 31MH-ij (i = 1 to 32, j = 1 to 24) are formed as pairs of rectangular parallelepiped through holes that bisect the portion symmetrically with respect to the midpoint of the first side described above.

  Further, as shown in FIG. 5, an upper layer power supply port 23U and a lower layer power supply port 23L are provided in the substantially central portion of the bottom of the case 22, and the upper layer power supply port 23U and the lower layer power supply port 23L are respectively described above. Connected to the triplate lines 33UF and 33LF.

Each part of the dual-polarized antenna having such a configuration (hereinafter referred to as “first conventional example”) is linked as follows.
In the following, as to the matters that hold for any of the suffixes i (= 1 to 32) and j (= 1 to 24) added to the code as described above, these suffixes i and j are denoted by Use to describe.
The upper layer element 33UE-ij formed on the power supply board 33U is excited by a transmitter (not shown) via the upper layer power supply port 23U and the triplate line 33UF, and is, for example, connected to a communication satellite located on a geostationary orbit. Used to form links.

  The lower layer element 33LE-ij formed on the power supply substrate 33L is formed to have a size larger than that of the upper layer element 33UE-ij for transmission, and the thickness and relative dielectric constant of the dielectrics 32M and 32U and the lower layer slot 31MH-ij (ground Under the combination with the thickness of the conductor 31M), the distance from the upper layer element 33UE-ij is set to a suitable value in advance, so that it functions as a reflector in the wavelength range of the transmission wave supplied by the transmitter. To do.

  On the other hand, the frequency fr of the received wave arriving from the communication satellite is set in advance to a value lower than the frequency ft of the transmitted wave supplied to the upper layer element 33UE-ij by the transmitter described above.

  The received wave of such a frequency fr is combined with the upper layer slot 31TH-ij and the dielectric 32T and the upper layer element 33UE-ij functioning as a director, and the dielectric 32U, the lower layer slot 31MH-ij and the dielectric 32M. To the lower layer element 33LE-ij, and further input to a receiver (not shown) via the triplate line 33LF and the lower layer power supply port 23L.

  Therefore, the element upper layer element 33UE-ij and the lower layer element 33LE-ij described above are used for wireless transmission via uplink and downlink links formed by linearly polarized waves orthogonal to each other between the common communication satellites. .

Although the first conventional example has been described in terms of comparison with the present invention, it corresponds to the polarization sharing planar antenna disclosed in Patent Document 1 described later.
Moreover, the main part of the polarization sharing antenna shown in FIG. 6 may be configured as follows, as shown in FIG. In the following, components having the same configuration and function as those shown in FIG. 6 are given the same reference numerals, and description thereof is omitted here.

(1) A ground conductor 41M is provided instead of the ground conductor 31M.
(2) Power supply boards 43U and 43L are provided in place of the power supply boards 33U and 33L, respectively.
(3) On the power supply substrate 43L, the triplate line 43LF formed in the direction of the diagonal line of the lower layer element 33LE-ij from each corner of the lower layer element 33LE-ij is replaced with the above-described triplate line 33LF. Provided.

(4) On the power supply substrate 43U, the triplate line formed in the direction of the diagonal line of the upper layer element 33UE-ij from each corner of the upper layer element 33UE-ij and perpendicular to the triplate line 43LF 43UF is provided instead of the above-described triplate line 33UF.
(5) In the ground conductor 41M, a lower layer slot 41MH-ij (i = 1 to 32, j = 1 to 24) is formed in place of the above-described lower layer slot 31MH-ij. These lower layer slots 41MH-ij are square portions facing the upper layer element 33UE-ij on the diagonal line of the upper layer element 33UE-ij from the connection point between the upper layer element 33UE-ij and the triplate line 43UF. Are formed as a pair of triangular through-holes, each of which is divided into two.

The dual-polarized antenna having such a configuration (hereinafter referred to as “second conventional example”) differs from the first conventional example in the following points.
All the elements 33UE-ij are fed from a direction different by 45 degrees in a specific direction with respect to the center of these elements 33UE-ij in comparison with the first conventional example. In addition, the lower layer element 33LE-ij is fed from a direction different from the first conventional example by 45 degrees in the same specific direction with respect to the center of the lower layer element 33LE-ij.

Therefore, the polarizations of the elements 33UE-ij and 33LE-ij are orthogonal to each other. However, in contrast to the first conventional example, the polarizations of the elements 33UE-ij and 33LE-ij are 45 in the same direction with respect to the centers of the elements 33UE-ij and 33LE-ij. It becomes the direction rotated by degrees.
On the other hand, since the lower layer slot 41MH-ij is formed as a pair of triangular through holes as described above, the lower layer slot 41MH-ij matches the rotation of the polarization and reflects the transmission of the lower layer element 33LE-ij. And the function as a director of the element 33UE-ij for the received wave.

Although the second conventional example has been described from the viewpoint of comparison with the present invention, it corresponds to the planar antenna disclosed in Patent Document 2 described later.
As prior arts related to the present invention, there are Patent Documents 1 to 3 listed below.

(1) “The ground conductor 30b of the intermediate layer is parallel to the feeder line 13a on the upper layer side and its extension line in the portion of the conductive thin plate corresponding to the radiating elements 12a and 12b, and is sufficiently larger than the width of the radiating element 12a. By making the structure and shape of the divided slot opening 31b and the bridge 32b formed by cutting the both sides of the thin conductive plate in the form of a bridge with a narrow width " "Improve isolation characteristics, reduce cross-polarization level during upper layer feeding, improve main polarization E-plane directivity gradient, and improve front gain without degrading the antenna characteristics" There is a polarization shared planar antenna ... Patent Document 1

(2) “The planar antenna 10 includes a power supply substrate 15 and a dielectric 16 which are reception-side substrates on which a ground conductor 11, a dielectric 12, a radiating element 13 and a power supply line 14 are formed from the lower layer side to the upper layer side. , A grounding conductor 18 having a slot opening 17 formed so as to be positioned directly above the radiating element 13, a dielectric 19, a radiating element 20, and a feeding substrate 22, which is a transmitting substrate on which a feeding line 21 is formed, 23, a ground conductor 25 having a slot opening 24 formed so as to be positioned directly above the radiating element 20, and an angle τ between the horizontal polarization direction and the X-axis direction is 40 degrees ≦ | τ | ≦ 50 degrees A flat antenna characterized in that “a linearly polarized signal having a wider polarization offset angle than that of the conventional one can be transmitted and received” by using the configuration described above.

(3) “The radiation holes provided in the middle-layer ground conductor 4 are formed in a grid shape in a direction perpendicular to the first polarization, and the radiation elements in the upper layer radiation circuit 5 are arranged in a grid in the direction perpendicular to the first polarization. By configuring as a radiating element ”, a dual-polarization planar antenna characterized by“ easy design and good isolation characteristics between polarizations ”. Patent Document 3

JP 2002-076767 JP 2010-206683 A JP-A-6-237119

  By the way, in the first conventional example described above, the lower layer element 33LE-ij and the upper layer element 33UE-ij are arranged with respect to the arrangement direction in which the lower layer element 33LE-ij and the upper layer element 33UE-ij are arranged in a lattice pattern. Since the polarization directions are orthogonal or parallel, the side lobe levels in the polarization planes of the lower layer element 33LE-ij and the upper layer element 33UE-ij are high. For example, JCSAT-1B, -2A, -3A, -4A It was difficult to adapt to all major domestic communication satellites such as -5A, Superbird B2, C, C2, etc.

  On the other hand, according to the second conventional example, the lower layer element 33LE-ij and the upper layer element 33UE-ij are arranged with respect to the arrangement direction in which the lower layer element 33LE-ij and the upper layer element 33UE-ij are arranged in a lattice pattern. Since the direction of polarization is inclined by about 45 degrees, the sidelobe level is reduced, and adaptation to all of the major domestic communication satellites is achieved.

  However, in the second conventional example, as indicated by a thick arrow in FIG. 8A, the lower layer element 33LE-ij arranged on the power supply substrate 43L and the lower layer element 33LE-ij on the power supply substrate 43U. Coupling between two or four upper layer elements 33UE-ij (hereinafter referred to as "adjacent elements") adjacent to the immediately adjacent upper layer element 33UE-ij is any feeding point of the lower layer element 33LE-ij. Since the position is asymmetric with respect to the adjacent element, it is not canceled out as in the first conventional example. Hereinafter, such a bond is referred to as “interlayer bond”.

  Therefore, the isolation between the lower layer element 33LE-ij arranged on the power supply substrate 43L and the upper layer element 33UE-ij arranged on the power supply substrate 43U is greatly reduced as compared with the first conventional example. .

Further, the lower layer element 33LE-ij is also coupled to other elements adjacent to the lower layer element 33LE-ij on the power supply substrate 43L, as shown by a thick arrow in FIG. 8B. In the following, such coupling is referred to as “intra-layer coupling” because it is distinct from the above “interlayer coupling”.
In the second conventional example, any of the received waves individually arriving at the other elements are received without canceling the “intra-layer coupling” described above, unlike the first conventional example. In addition, the cross-polarization discrimination is a factor that deteriorates.

Note that, in the power supply substrate 43U, similarly to the above-described “intra-lower layer coupling”, coupling occurs between upper layer elements arranged adjacent to the power supply substrate 43U (hereinafter, “intra-upper layer coupling”).
However, such an intra-layer coupling occurs in a portion near the opening of the upper layer slot 31TH-ij as compared to the interlayer coupling and the lower layer coupling described above, and therefore, the generation amount of the parallel plate mode is small. It is not a factor that greatly affects the cross polarization discrimination.

  SUMMARY OF THE INVENTION An object of the present invention is to provide a dual-polarized antenna that can improve cross-polarization discrimination and isolation between transmission and reception ports at a low cost without greatly complicating the configuration.

  According to the first aspect of the present invention, a plurality of first antenna elements that are formed in a grid pattern or a line pattern on a predetermined surface and that have power feeding paths individually formed in a common direction; A plurality of second antenna elements formed respectively facing each of the first antenna elements and having a feeding path formed in a specific direction orthogonal to the common direction. The antenna elements individually have slits or notches formed in the specific direction.

  That is, since the plurality of second antenna elements are divided in a direction perpendicular to or intersecting with the specific direction by individually having slits or notches formed in the specific direction, The resonance frequency shifts to a higher value.

  According to a second aspect of the present invention, in the dual-polarized antenna according to the first aspect, the plurality of second antenna elements are larger than the plurality of first antenna elements.

  That is, when the resonance frequency of the plurality of first antenna elements is higher than the resonance frequency of the plurality of second antenna elements, the first antenna element and the second antenna element are respectively a director and Functions as a reflector.

  According to a third aspect of the present invention, in the dual-polarized antenna according to the first aspect, the plurality of second antenna elements are smaller than the plurality of first antenna elements.

  That is, when the resonance frequencies of the plurality of first antenna elements are lower than the resonance frequencies of the plurality of second antenna elements, the first antenna element and the second antenna element are respectively a reflector and a conductor. Functions as a waver.

  According to a fourth aspect of the present invention, in the polarization sharing antenna according to any one of the first to third aspects, a plurality of the slits or notches are formed continuously in the specific direction.

  That is, a plurality of first antenna elements and a plurality of second slits or notches are formed even if the above-described resonance frequency shift is reduced by forming a plurality of slits or notches in the specific direction. As long as any of the coupling between the antenna elements and the coupling between the antenna elements adjacent to each other among the plurality of second antenna elements is sufficiently rough, various shapes, dimensions, and It can be formed by arrangement.

  According to a fifth aspect of the present invention, in the dual-polarized antenna according to any one of the first to fourth aspects, a plurality of the slits or notches are formed in parallel with the specific direction.

  That is, even when the plurality of slits or notches are formed in parallel to the specific direction to reduce the resonance frequency shift described above, the plurality of first antenna elements and the plurality of second antennas are reduced. As long as any of the coupling between the antenna elements and the coupling between the antenna elements adjacent to each other among the plurality of second antenna elements is sufficiently rough, various shapes, dimensions, and It can be formed by arrangement.

According to the present invention, the coupling between the plurality of first antenna elements and the plurality of second antenna elements, and the coupling between the antenna elements adjacent to each other among the plurality of second antenna elements. In either case, the configuration becomes rough without being greatly complicated.
Further, in the present invention, polarization sharing by two linearly polarized waves orthogonal to each other is realized with a high gain by adapting to each resonance frequency of the antenna element corresponding to these linearly polarized waves.
Furthermore, the present invention can alleviate the restrictions on the shape, size, arrangement, etc. of the plurality of first and second antenna elements, and can be applied to various fields.
Further, in the radio transmission system to which the present invention is applied, the cross polarization discrimination degree and the isolation between the transmission and reception ports are increased, so that the transmission speed and the transmission quality are improved, and the transmission system and the reception system are inexpensive. Miniaturization is achieved.

It is a figure which shows one Embodiment of this invention. It is a figure which shows the isolation improved by this embodiment. It is a figure which shows the cross polarization discrimination degree improved by this embodiment. It is a figure which shows the other aspect of the slit in this embodiment.

It is a figure which shows the structural example of a polarization shared antenna. It is a figure (1) which shows the detailed structure of the slot and feed system in the conventional polarization sharing antenna. It is a figure (2) which shows the detailed structure of the slot and feed system in the conventional polarization sharing antenna. It is a figure which shows the subject of the conventional polarization shared antenna.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.
FIG. 1 is a diagram showing an embodiment of the present invention.
In the figure, components having the same configuration and functions as those shown in FIG.

  As compared with the second conventional example shown in FIG. 7, the feature of the configuration of the present embodiment is that the lower layer element 33LE-ij (i = 1 to 32, j = 1 to 24) as shown in FIG. The slit 11-ij (i = 1 to 32, j = 1 to 24) is formed in a predetermined section on the diagonal line of the lower layer element 33LE-ij from the vicinity of the connection point with the triplate line 43LF. is there.

Hereinafter, the operation and effect of the present embodiment will be described with reference to FIG.
The lower layer element 33LE-ij is formed with the slit 11-ij as described above, but is supplied with power through the triplate line 43LF and has the same characteristics as those of the second conventional example shown in FIG. It functions as an element and also functions as a reflector for transmission by cooperating with the upper layer element 33UE-ij.

  Further, in the present embodiment, the lower layer element 33LE-ij is physically divided into two by forming the slit 11-ij, so that the lower layer element 33LE-ij is substantially divided into two sides with small dimensions.

  Therefore, in the above-described “interlayer coupling” and “intra-layer coupling” coupling, the resonance frequency in the cross polarization direction (direction perpendicular to the longitudinal direction of the slit) of the lower layer element 33LE-ij is the slit 11-ij. Since the value shifts to a higher value in two minutes, the result is much rougher than in the second conventional example.

  As described above, according to the present embodiment, the isolation between the transmission and reception ports and the above-described cross polarization discrimination can be increased at low cost without greatly complicating the configuration. In this embodiment, the isolation between the transmission and reception ports is improved by about 25 dB in the reception band as shown by the solid line and the dotted line in FIG. 2, and the cross polarization discrimination is as shown in FIG. Is improved by about 5 dB.

  Therefore, in the wireless transmission system to which the present embodiment is applied, it is possible to reduce the size and cost of the filter to be mounted on the transmitter and the receiver, and to improve the transmission speed and transmission quality by increasing the CN ratio. Is planned.

In the present embodiment, triplate lines 43UF and 43LF are connected to the upper layer element 33UE-ij and the lower layer element 33LE-ij, respectively, as feeding paths.
However, such a power feeding path may be formed as any of an open type, an unbalanced type planar circuit, a coaxial cable or the like instead of the triplate lines 43UF and 43LF, and includes a through hole. May be.

Furthermore, in the present embodiment, the upper layer element 33UE-ij and the lower layer element 33LE-ij are unbalanced and fed by the triplate lines 43UF and 43LF, respectively.
However, the upper layer element 33UE-ij and the lower layer element 33LE-ij may be balancedly fed by, for example, forming the upper layer element 33UE-ij and the lower layer element 33LE-ij as a balanced feeding path.

In the present embodiment, the characteristics of the power feeding path are suitably set according to the shapes, dimensions, and characteristics of the ground conductors 31L, 41M, and 31T and the dielectrics 32L, 32M, 32U, and 32T.
However, these ground conductors 31L, 41M, and 31T and the dielectrics 32L, 32M, 32U, and 32T may be replaced with other members (feeding boards 43U and 43L) as long as the overall characteristics as a polarization sharing antenna are secured. May be substituted or not provided).

  Furthermore, in the present embodiment, the upper layer element 33UE-ij and the lower layer element 33LE-ij may be any member on which they are formed and supported as long as the above-described effects are achieved. Any member may be interposed between the power supply substrates 43U and 43L.

  In the present embodiment, the upper layer element 33UE-ij and the lower layer element 33LE-ij are formed on planes on the power supply substrates 43U and 43L, respectively.

  However, the surface on which the upper layer element 33UE-ij and the lower layer element 33LE-ij are to be formed or disposed is flat if a dual-polarized antenna having desired characteristics is realized by applying the present invention. For example, it may be a curved surface such as a spherical surface, or a surface that bends discontinuously.

  Further, in the present embodiment, the upper layer element 33UE-ij and the lower layer element 33LE-ij are arranged at a constant interval in a lattice of 32 columns × 24 rows.

  However, the upper layer element 33UE-ij and the lower layer element 33LE-ij may be arranged at indefinite intervals or arranged in a row as long as the above-described effects are impaired.

  In the present embodiment, the slit 11-ij divides the lower layer element 33LE-ij in the polarization direction, thereby shifting the resonance frequency of the lower layer element 33LE-ij in the cross polarization direction to a high value. .

  However, for such a slit 11-ij, in order to shift the resonance frequency in the cross polarization direction of the lower layer element 33LE-ij to a high value, the current distribution on the lower layer element 33LE-ij is divided into a plurality of sections. If the lower layer element 33LE-ij can function as the reflector described above, the shape (including the comb shape), dimensions, and arrangement are exemplified as shown in FIGS. 4 (a) to 4 (e), for example. Any number may be used, and even when there are a plurality of numbers, all or part of the numbers may be formed as notches.

Further, in the present embodiment, the lower layer element 33LE-ij is fed in parallel via the common triplate line 43LF.
However, such lower layer element 33LE-ij (i = 1 to 32, j = 1 to 24) may be fed by, for example, a feeding path (feeding system) that realizes beam forming or null steering.

  In the present embodiment, any multiple access scheme, frequency arrangement, and modulation scheme are applied to the uplink and the downlink that are formed via the upper layer element 33UE-ij and the lower layer element 33LE-ij, respectively. Good.

  Further, in the present embodiment, the shapes of the upper layer element 33UE-ij and the lower layer element 33LE-ij are not limited to the above-described squares. For example, rhombuses, rectangles (rounded four corners, or all or part of the sides) Including those having a constriction), a circle, an ellipse, or the like.

  In the present embodiment, the lower layer slot 41MH-ij (i = 1 to 32, j = 1 to 24) formed in the ground conductor 41M is interposed between the pair of triangular through holes described above. As shown by a dotted frame in FIG. 1, a conductor bridge is formed.

  However, there is no need for such a bridge as long as the above-described isolation and the reduction of the orthogonal polarization discrimination degree are allowed.

  Furthermore, in the present embodiment, the shape of the upper slot 31TH-ij is not limited to a rectangle as long as desired characteristics are achieved by the dual-polarized antenna according to the present embodiment. It may be anything, and may have any dimensions and arrangement.

  In the present embodiment, the upper layer slot 31TH-ij may not be provided together with the ground conductor 31T (and the dielectric 32T).

  Further, in the present embodiment, the lower layer slot 41MH-ij is not limited to the above-described shape as long as the desired characteristics of the dual-polarized antenna are achieved, and may be any shape such as a circle, a rhombus, an ellipse, or the like. Any size and arrangement may be used.

  In the present embodiment, the upper layer element 33UE-ij and the lower layer element 33LE-ij are used for transmission and reception, respectively.

  However, when the upper layer element 33UE-ij and the lower layer element 33LE-ij need to function as a director and a reflector, respectively, the frequency of the transmission wave is set lower than the frequency of the reception wave, and these The upper layer element 33UE-ij and the lower layer element 33LE-ij may be connected to the receiver and the transmitter, respectively.

  Further, as for the dimensions of the upper layer element 33UE-ij and the lower layer element 33LE-ij, the former may be set larger or the same as the latter according to the frequency relationship between the transmission wave and the reception wave.

  Further, in the present embodiment, the present invention is not limited to the formation of a wireless transmission path with a communication satellite on a geostationary orbit, but various communications in which a desired wireless transmission path should be formed by linearly polarized waves orthogonal to each other. It can also be applied to transmission systems and transmission systems.

  Further, the present invention is not limited to the above-described embodiments, and various configurations of the embodiments are possible within the scope of the present invention, and any improvements may be made to all or some of the components.

11 Slit 21 Elastic member 22 Case 23L Lower layer power supply port 23U Upper layer power supply port 31L, 31M, 31T, 41M Ground conductor 33LE Lower layer element 33LF, 33UF, 43LF, 43UF Triplate line 31MH, 41MH Lower layer slot 31TH Upper layer slot 33UE Upper layer element 32L, 32M, 32U, 32T Dielectric 33L, 33U, 43U, 43L

Claims (5)

A plurality of first antenna elements formed in a grid or a row on a predetermined surface, and the feeding paths are individually formed in a common direction;
A plurality of second antenna elements that are respectively formed facing the plurality of first antenna elements and in which feed paths are individually formed in a specific direction orthogonal to the common direction;
The plurality of second antenna elements are:
The polarization-sharing antenna characterized by having individually slits or notches formed in the specific direction. The dual-polarized antenna according to claim 1,
The plurality of second antenna elements are:
The polarization sharing antenna, wherein the antenna is larger than the plurality of first antenna elements. The dual-polarized antenna according to claim 1,
The plurality of second antenna elements are:
The dual-polarized antenna, wherein the antenna is smaller than the plurality of first antenna elements. The dual-polarized antenna according to any one of claims 1 to 3,
The slit or notch is
A polarization sharing antenna, wherein a plurality of antennas are formed continuously in the specific direction. The dual-polarized antenna according to any one of claims 1 to 4,
The slit or notch is
A plurality of polarization sharing antennas, wherein the antenna is formed in parallel with the specific direction.