JP3137260B2 - Radial line slot antenna - Google Patents

Description

DETAILED DESCRIPTION OF THE INVENTION [Industrial Application Field] The present invention relates to a radial line slot antenna using a radial waveguide used in SHF and EHF bands.

[Conventional technology]

As a prior art, for example, there is one disclosed in Japanese Patent Publication No. 64-1965. That is, the wavelength of the propagation mode, which is the most fundamental propagation mode in the radial waveguide composed of the upper and lower disc-shaped conductors arranged at equal intervals and spreads uniformly from the center in the radial direction with the same intensity, is λ. _g , the first conductor at a distance of δ from the center on the radial axis of the upper conductor.
Point, on an axis perpendicular to this axis, from the center δ + 1/4 × λ _g
A third point at a distance of δ + 1/2 × λ _g coaxial with the second point and the first point and opposite to the first point from the center and coaxial with the second point. A fourth point at a distance of δ + 3/4 × λ _{g on} the opposite side of the second point from the center, and a fifth point at a distance of δ + λ _g from the center in the same direction and in the same direction as the first point. points, and the spiral lines sequentially through a group of points defined by the same manner, the radiating element comprises a set of slots disposed at the center distance of each other in 1/4 × λ _g in the orthogonal line, A circularly polarized planar array antenna characterized in that one of the slots is sequentially arranged in a substantially C-shape having an inclination of about 45 ° with respect to the radial direction.

[Problems to be solved by the invention]

However, the conventional antenna described above, because the spacing between the spiral adjacent to each other is lambda _g, the influence of grating lobes is relatively large, there is a problem that it is impossible to obtain a sufficient gain. Further, although also made possible to suppress the grating lobes of lambda _g was shorter than the spatial wavelength lambda _0, since lambda _g is close to the value of lambda _0, it can not be suppressed grating lobes enough, sufficient gain I can't get it.

In general, it is known that the shorter the slot interval, the smaller the effect of the grating lobe. Therefore, it is conceivable to suppress the grating lobe by arranging the slots densely. In this case, the problem of how to radiate radio waves vertically from the radial waveguide and make it circularly polarized must be solved.

 The present invention has the above object as its object.

It is another object of the present invention to provide a circularly polarized radial line slot antenna in which the influence of the grating lobe is small and a sufficient gain is obtained.

[Means for solving the problem]

The present invention has been made to solve the above problems,
When the wavelength is lambda _g of the radial waveguide consists of two conductors which face substantially at equal intervals, on the radial axis of the upper conductor, a first point at a distance of from the center [delta], [delta]
A second point at a distance of + λ _g , a third point at a distance of δ + 2 × λ _g , and on a first spiral consisting of Archimedes' spirals passing through a group of points obtained in the same manner; Coaxial with the point and on the same side as this first point, from its center δ + 1/2
The first point at a distance of × λ _g , (δ + 1/2 × λ _g ) +
The second point at a distance of λ _g , (δ + 1/2 × λ _g ) +2
A radial line slot antenna comprising a slot formed on a second screw consisting of an Archimedean screw passing through a third point at a distance of × λ _g , and a point group obtained in the same manner. A slot formed on one spiral,
The slots formed on the second screw are formed in the same direction on each screw, and on the same radial axis, the direction of the slot formed on the second screw is The slot formed on the first spiral is aligned with the same radial axis passing through the center of the slot.
A radial line slot antenna formed in a direction rotated by 0 degrees.

[Action]

The radial line slot antenna of the present invention has
1/2 × a lambda _g 2 pieces of spiral, i.e. respectively so to form a slot on the first spiral and the second spiral, the arrangement of the slots becomes dense, the grating lobe is suppressed, further Since the slot formed on the first spiral and the slot formed on the second spiral are arranged in a direction rotated by 180 degrees with respect to each other, the radiated radio waves are circularly polarized in the same phase. Is resolved.

〔Example〕

 The present invention will be described in detail with reference to examples.

FIG. 1 is an explanatory view of a radial line slot antenna according to the present invention. In FIG. 1, (1) is a slot plate, and the slot plate (1) is a metal disk, which is formed by etching or the like. Slot (2).
Further, (3) is a frame, and the frame (3) is obtained by drawing a peripheral edge of a metal disk, and the slot plate (1) is joined to the peripheral edge, sealed with an epoxy resin or the like, and a radial is inserted therein. A waveguide (4) is formed. That is, a radial waveguide (4) is formed by two conductors consisting of the slot plate (1) and the bottom of the frame (3). At the approximate center of the slot plate (1), a coaxial (5) is attached.

A partition plate (not shown) is disposed in an internal space formed by the slot plate (1) and the frame (3), and the radial waveguide (4) is divided into an upper waveguide and a lower waveguide.
A folded portion of the waveguide may be formed on the outer periphery of the partition plate.

A radome (6) is mounted on the slot plate (1) to prevent intrusion of rain or the like. The radome (6) is formed of a Teflon material or the like which is easy to slip so that snow or the like does not accumulate, and its periphery is overlapped with the slot plate (1) and the frame (3) and sealed. Further, a spacer (7) made of styrene foam or the like may be laminated between the radome (6) and the slot plate (1) as necessary.

Next, an arrangement pattern of the slots (2) provided in the slot plate (1) will be described.

As shown in FIG. 2, a slot (2) consisting of a pair of slots forming a C-shape is formed on two spirals, namely a first spiral (11) and a second spiral (12). . The first screw (11) is a first point, δ + λ _g , which is a distance δ from the center O of the slot plate (1), where λg is the wavelength of the axially symmetric propagation mode in the radial waveguide (4). , A third point at a distance of δ + 2 × λ _g , and a point group obtained in the same manner, that is, an Archimedes spiral passing through a point group given at an interval of λ _g . That is, the polar coordinates (R, θ) of the midpoint of slot (2) are given by the equation R =
Slots (2) are sequentially arranged so as to satisfy δ + λ _g × θ / 2π.

On the other hand, the second spiral line (12) is coaxial with the first point and is δ + 1/2 × λ _g from the center thereof on the same side as the first point.
1 ′ point at a distance of (δ + 1/2 × λ _g ) + λ _g , a second ′ point at a distance of (δ + 1/2 × λ _g ) + 2 × λ _g
Third 'point, point group obtained in the same manner, i.e. first' in the Distance consisting Archimedean spiral which passes through the lambda _g point group given by the intervals in terms of. That is, the polar coordinates (R, θ) of the midpoint of slot (2) are given by the equation R = δ +
Slots (2) are sequentially arranged so as to satisfy 1/2 × λ _g + λ _g × θ / 2π. The slot (2a) formed on the first spiral and the slot (2b) formed on the second spiral are respectively formed in the same direction, and are formed on the first spiral. The slot formed on the second spiral and the slot formed on the second spiral are rotated 180 degrees from each other.

As described above, by defining the first spiral line (11) and the second spiral line (12), the interval between these spiral lines is 1/2 × λ.
_g , which is shorter than the conventional one. This interval is set to 1/2 × λ _g . In order to radiate radio waves to the antenna element, that is, the slot, the interval between the slots must be an integral multiple of 1/2 × λ _g. Because it does not become.

On the other hand, in order to achieve circular polarization, the orientation of the slots formed on the first spiral line (11) and the second spiral line (12) must be the same on each spiral line. However, as in the present invention, the interval between the slots is 1/2.
In the case of × λ _g, the phases radiated from adjacent slots are opposite, and eventually cancel each other out, so that radio waves are not radiated.
Therefore, in the present invention, two spirals are used, and the first spiral (1
1) The slot (2a) formed on the upper surface and the slot (2b) formed on the second screw (12) are formed in a state of being rotated by 180 degrees with respect to each other. That is, in the present invention, the interval is 1 /
Two spiral is 2 × lambda _g, i.e. with a first spiral and the second spiral, forming a slot on these, moreover slot and a second screw line formed on a first helix By rotating the slots formed by 180 degrees with respect to each other, the slots can be densely arranged to suppress the grating lobe, increase the gain, and radiate radio waves from the slots with circular polarization.

〔The invention's effect〕

The radial line slot antenna according to the present invention can obtain a circularly polarized radial line slot antenna having a small influence of the grating lobe and a high gain performance.

[Brief description of the drawings]

The drawings show an embodiment of the present invention, FIG. 1 is an explanatory view in which a part thereof is cut away, and FIG. 2 is an explanatory view of a slot pattern. (1) Slot plate (2) Slot (3) Frame (4) Radial waveguide (5) Coaxial (6) Radome (7) Spacer (11) 1st spiral (12) ... 2nd spiral

Claims (1)

(57) [Claims] When the wavelength in a radial waveguide composed of two conductors opposed at substantially equal intervals is λg,
A first point on the radial axis of the upper conductor at a distance of δ from its center, a second point at a distance of δ + λg, δ + 2 × λ
g, on a first spiral consisting of Archimedes' spirals passing through a group of points obtained in the same way, and on the same side as the first point, coaxially with said first point. The first point at a distance of δ + 1/2 × λg from the center, (δ + 1/2
× λg) + the second point at a distance of λg, (δ + 1/2 ×
λg) + 2 × λg, a radial line slot antenna having a slot formed on a second spiral consisting of an Archimedes spiral passing through a point group obtained in the same manner, The slot formed on the first spiral and the slot formed on the second spiral are formed in the same direction on the respective spirals, and further, on the same radial axis, The orientation of the slot formed on the two spirals is such that the slot formed on the first spiral is rotated by 180 degrees with respect to the same radial axis passing through the center of the slot. Radial line slot antenna.