RU2199804C2 - Antenna - Google Patents

Abstract

FIELD: radio engineering; antenna-feeder devices. SUBSTANCE: device that may be used as linearly polarized directional antenna has contiguously interconnected two rhomboid sections and at least one additional rhomboid section. Conductors are disposed over perimeter of rhomboid sections. Gap provided between conductors of two rhomboid sections at point of their connection is used for connecting to additional-feeder conductors. Additional rhomboid section conductors are crosswise connected to conductors disposed in same direction as the latter over perimeter of adjacent rhomboid section. Angles of two rhomboid sections and of additional rhomboid section facing common longitudinal axis of set of rhomboid sections are obtuse angles. EFFECT: reduced width of directivity pattern and enhanced efficiency. 7 cl, 8 dwg

Description

 The invention relates to radio engineering and can be used in antenna-feeder devices as a directional antenna of linear polarization.

 A double square antenna type is known, containing two rhomboid sections, along the perimeter of which conductors are located, while the conductors of one rhomboid section are connected to the conductors of another rhomboid section with crossing conductors located in the same direction along the perimeter of an adjacent rhomboid section and with an interval between crossed conductors [1].

 In this technical solution, the rhomboid sections are arranged in parallel planes, and one of the rhomboid sections performs the function of a vibrator made in the form of a wire square with side length λ / 4, where λ is the average wavelength and the total length of the perimeter of the section is 1λ. The second rhomboid section serves as a reflector. The total length of the perimeters of the two sections is 2λ. Crossing conductors with a gap between them in this technical solution is used only for the spatial placement of rhomboid sections in parallel planes. Such an antenna is directional, but does not have a high coefficient of directional action (KND).

 Closest to the claimed one is an antenna containing two rhomboid sections and at least one additional rhomboid section located in the same plane, connected adjacent to each other in a row, along the perimeter of which there are conductors, their length being selected satisfying the condition for the formation of short dots closures at the vertices of the rhomboid sections located opposite to the junction of the rhomboid sections at a maximum distance from each other on the common longitudinal axis of the row p mbo-shaped sections, and at the junction of the two rhomboid sections between their conductors, a gap is made for connecting to the conductors of a two-wire feeder, while the conductors of the additional rhomboid section are connected to the conductors located in the same direction along the perimeter of the adjacent one rhomboid section, with the conductors crossing between these rhomboid sections, and the aforementioned crossing of the conductors is performed with a gap between them [2].

 Such an antenna allows you to theoretically increase in the required quantity the number of rhomboid sections to obtain a narrow radiation pattern.

 However, in practice, the number of rhomboid sections is limited due to radiation energy loss.

 The problem solved by the invention is the improvement of the technical and operational parameters of the antenna.

 The technical result that can be obtained by performing the antenna is to increase the effective aperture of the antenna with a uniform distribution of current over the rhomboid sections, which leads to a narrowing of the radiation pattern and an increase in directivity gain.

 An additional technical result, which was obtained when performing the antenna, is the expansion of the working frequency band.

 To solve the problem with achieving the specified technical result in an antenna containing two rhomboid sections and at least one additional rhomboid section located in the same plane, connected adjacent to each other in a row, along the perimeter of which there are conductors whose length is selected to satisfy the condition for the formation of short circuit points at the vertices of the rhomboid sections located opposite to the junction of the rhomboid sections at a maximum distance d a friend from each other on the common longitudinal axis of a number of rhomboid sections, and at the junction of two rhomboid sections between their conductors, a gap is made that is transverse to the common longitudinal axis and designed to connect a two-wire feeder to the conductors, while the conductors of the additional rhomboid section are connected to the conductors located in the same direction along the perimeter of the adjacent one rhomboid section, with the crossing of conductors between these rhomboid sections, and omyanutoe crossing of the conductors formed with a gap between them, according to the invention, two diamond-shaped corners sections and additional diamond-shaped section facing the common longitudinal axis a number of diamond-shaped sections are made blunt.

Additional embodiments of the device are possible, in which it is advisable that:
- the total number of said rhomboid sections was chosen odd;
- the total number of said rhomboid sections was chosen even;
- the said angles of the rhomboid sections facing the common longitudinal axis and located closer to the gap of the two rhomboid sections intended to be connected to the conductors of the two-wire feeder, were chosen larger than the mentioned angles of the rhomboid sections located further from the gap of the two rhomboid sections;
- a flat screen was introduced, parallel to the plane of arrangement of the said rhomboid sections, and racks connected by one ends at the vertices of the rhomboid sections located at the maximum distance from each other on a common longitudinal axis, and by the other ends to the flat screen, were introduced, with the flat screen made rectangular, its length is not less than the distance between the vertices of the rhomboid sections located at a maximum distance from each other along a common longitudinal axis, and the width is made larger em λ / 2 and the length of the small diagonal of the diamond-shaped section, the distance S between the plane of arrangement of the flat screen and a plane arrangement of diamond-shaped sections is selected to meet the condition 0,15≤S / λ≤0,27, where λ - mean wavelength;
- plate-shaped reflectors were introduced, located on both sides of the extreme rhomboid sections and whose overall dimension in the orthogonal plane to the flat screen is made smaller than the distance S from the plane of the flat screen to the plane of the arrangement of the rhomboid sections;
- a plate director was introduced, located symmetrically and parallel to the rhomboid sections, the maximum length of the plate director was chosen equal to the total length of the diagonals of the rhomboid sections along a common longitudinal axis, and the rhomboid sections are located between the flat screen and the plate director.

 By choosing the angles of the rhomboid sections, it was possible to solve the problem with the achievement of the specified technical result.

 These advantages, as well as features of the present invention are illustrated by the best options for its implementation with reference to the accompanying figures.

Figure 1 schematically depicts an antenna with the number of rhomboid sections equal to three;
figure 2 is the same as figure 1, with the number of rhomboid sections equal to four;
figure 3 is the same as figure 1, with the number of rhomboid sections equal to six;
figure 4 is the same as figure 2, with a flat screen;
figure 5 - various designs of reflectors;
FIG. 6 shows a design of a flat screen and a director without showing rhomboid sections between them.

 The antenna (figure 1) contains two rhomboid sections 2 and at least one additional rhomboid section 3. Two rhomboid sections 2 and at least one additional rhomboid section 3 are located in the same plane, are connected adjacent to each other in a row , and conductors 4 are located along their perimeter. The length of the conductors 4 is selected to satisfy the condition for the formation of short circuit points at the vertices 5 of the rhomboid sections 2, 3 located opposite to the gap 6 at a maximum distance from uga on a common longitudinal axis X number of diamond-shaped sections 2, 3. For this purpose the length of the conductors 4 sides of said diamond-shaped sections 2, 3 is selected ≅ λ / 4. At the junction of the two rhomboid sections 2 between their conductors 4, a gap 6 is made. The vertices 7 of the angles between the conductors in the gap 6 of the two rhomboid sections 2 are designed to connect a two-wire feeder to them (not shown in Figs. 1-4).

 The conductors 4 of the additional rhomboid-shaped section 3 are connected to the conductors 4 located in the same direction along the perimeter of the adjacent rhomboid-shaped section 2, with the crossings of the conductors 4 between these rhomboid-shaped sections 2, 3. The mentioned crossing of the conductors 4 (shown in Figs. 1-4 by an arc) made with a gap between them without the formation of galvanic contact.

The angles α _{1 of the} two rhomboid sections 2 and the angle α _{2 of the} additional rhomboid section 3, facing the common longitudinal axis X of a number of rhomboid sections 2, 3, are made obtuse, mainly more than 90 ^o and less than 145 ^o .

By making the angles α ₁ and α ₂ obtuse, it is possible to increase the size Ai (where i is the number of rhomboid sections 2, 3 along the common longitudinal axis X of the row) of the antenna, ceteris paribus - the same side length and the number of the rhomboid sections 2, 3 and improve uniform distribution of current across the conductors 4 in each rhomboid section 2, 3, remote from the points of introduction of the emf excitation (from the gap 6), which together narrows the antenna radiation pattern.

 If the total number of the mentioned rhomboid sections 2, 3 is chosen odd (Fig. 1), then the antenna broadband improves overall.

 If the total number of the mentioned rhomboid sections 2, 3 is chosen even (Figs. 2, 3), then a standard emitter is formed from these rhomboid sections 2, 3, but with an increased KND. The increase in the number of additional rhomboid sections 3 (figure 2, 3) allows you to increase KND.

To further expand the working strip, the angles α _{1 of} two rhomboid sections 2 located closer to the gap 6 of two rhomboid sections 2, intended to be connected to the conductors 4 of a two-wire feeder, are selected larger than the angles α _{2 of the} rhomboid sections 3 located further from the gap 6 of two rhomboid sections 2 (figure 1, 2). If, for example, the total number of rhomboid sections 2, 3 is six (Fig. 3), then α ₁ > α ₂ > α ₃ .

 The introduction of a flat screen 8 (figure 4), located parallel to the plane of the location of the said rhomboid sections 2, 3, allows you to narrow the radiation pattern of the antenna. The introduction of racks 9 connected at one end at the vertices 5 of the rhomboid sections 2 and 3 (FIG. 1) or additional rhomboid sections 3 (FIG. 4), and at the other ends to the flat screen 8, allows for decoupling of the antenna, as racks 9 are connected to the extreme rhomboid sections 3 at points of zero potential. The flat screen 8 (Fig.4, 6) is made rectangular. Its length L is not less than the distance Аi between the vertices 5 of the additional rhomboid sections 3 located at the maximum distance from each other along the common longitudinal axis X. The width B of the flat screen 8 is made larger than λ / 2 (or the length of the small diagonal of the rhomboid section 2 or 3 ) The distance S between the plane of arrangement of the flat screen 8 and the plane of arrangement of the rhomboid sections 2, 3 is selected satisfying the condition 0.15≤S / λ≤0.27.

 To further narrow the radiation pattern, plate reflectors 10 can be introduced into the device (Fig. 5). Plate reflectors 10 are located on both sides of the extreme additional rhomboid sections 3, and their overall dimension d in the orthogonal plane to the flat screen 8 is selected less than the distance S from the plane of the flat screen 8 to the plane of the arrangement of the rhomboid sections 2, 3 (Fig. 5) .

 To further narrow the radiation pattern, a plate director 11 can be inserted into the device (Fig. 6), located symmetrically and parallel to the said rhomboid sections 2, 3. The maximum length of the plate director 11 is chosen equal to the total length of the diagonals of the rhomboid sections 2, 3 along the common longitudinal axis X row. Rhomboid sections 2, 3 are located between the flat screen 8 and the plate director 11 (in Fig. 6, for simplification, rhomboid sections 2, 3 are not shown).

 As can be seen from Fig.1-3, the antenna feature is the convenience of connecting a two-wire feeder to the peaks 7. The part of the diamond-shaped sections 2, 3 symmetrical with respect to the transverse axis Y can be simply removed without compromising the quality of the antenna. Then the antenna is powered only on one side of the extreme rhomboid section 2 for all available rhomboid sections 3 rows.

 The antenna works as follows.

 Under the influence of the emf applied in the gap 6, currents occur on the conductors 4 of the rhomboid sections 2, 3 (Figs. 1-4). Due to the points of zero potential - the vertices 5 of one of the two rhomboid sections 2 and the additional rhomboid section 3 (Fig. 1) or the vertices 5 of the two extreme additional rhomboid sections 3 (Fig. 2-4), the intersections of the conductors 4 of the adjacent rhomboid sections 2 and additional rhomboid sections 3, as well as a selected length of the sides of the conductors 4 of said rhomboid sections 2, 3, selected ≅ λ / 4, all segments of the conductors 4 are phased with the orientation of the vector E parallel to the Y axis.

 The antenna at the same time functions as a kind of phased array antenna (PAR), which has one pair of power points, unlike conventional PAR. The antenna bottom appears to be narrower, the larger its size Аi.

 The flat screen 8 (FIGS. 4, 6) not only traditionally covers radiation in the back half-plane of space, but also further narrows the radiation pattern in the H-plane of polarization due to the action of the plate reflector 10.

 The plate director 11 (FIG. 6) is similar in principle to the well-known directors of wave-channel type antennas. In the proposed embodiment of the antenna, the plate director 11 narrows the beam in the E-plane of polarization immediately for the entire antenna due to its design (plate) of length Ai with selected width b.

Заявленное техническое решение в свою очередь можно неоднократно использовать как элемент антенной решетки на основе известных из уровня техники приемов и методов.Preferred size limits shown in FIGS. 1-6 are as follows:
gap

The claimed technical solution, in turn, can be repeatedly used as an element of the antenna array based on techniques known from the prior art.

 The most successfully claimed antenna can be industrially applicable as a directional antenna of linear polarization.

Sources of information
1. K. Rothammel, "Antennas", abbr. Translation from German T.E. Krenkel, Energy, Moscow, 1967, pp. 88-96, fig. 2-63.

2. Copyright certificate of the USSR 138277, 21 a ⁴ , 46 ₀₃ , publ. 1961

Claims (7)

 1. An antenna containing two rhomboid sections and at least one additional rhomboid section located in the same plane, connected adjacent to each other in a row, along the perimeter of which there are conductors whose length is selected to satisfy the condition for the formation of short circuit points at the vertices of rhomboid sections located opposite to the junction of the rhomboid sections at a maximum distance from each other on the common longitudinal axis of a number of rhomboid sections, and at the When two rhomboid sections are connected between their conductors, a gap is made that is transverse to the common longitudinal axis and designed to connect the two-wire feeder to the conductors, while the conductors of the additional rhomboid section are connected to the conductors located in the same direction along the perimeter of the adjacent one rhomboid section, with crossing conductors between these rhomboid sections, wherein said crossing of the conductors is performed with a gap between them, distinguishing by the fact that the angles of the two diamond-shaped sections and the additional diamond-shaped section facing the common longitudinal axis a number of diamond-shaped sections are made blunt.  2. The antenna according to claim 1, characterized in that the total number of said rhomboid sections is selected odd.  3. The antenna according to claim 1, characterized in that the total number of said rhomboid sections is selected even.  4. The antenna according to claim 3, characterized in that the said corners of the rhomboid sections facing the common longitudinal axis and located closer to the gap of the two rhomboid sections intended to be connected to the conductors of the two-wire feeder are selected larger than the mentioned corners of the rhomboid sections located further from the gap of two rhomboid sections.  5. The antenna according to claim 1, characterized in that a flat screen is introduced that is parallel to the plane of the location of the said rhomboid sections, and racks are connected that are connected at one end at the vertices of the rhomboid sections located at a maximum distance from each other on a common longitudinal axis, and others the ends to the flat screen, while the flat screen is made rectangular, its length is not less than the distance between the vertices of the rhomboid sections located at a maximum distance from each other along a common longitudinal axis, and the width is made larger than λ / 2 and than the length of the small diagonal of the rhomboid section, and the distance S between the plane of the flat screen and the plane of the rhomboid sections is selected satisfying the condition 0.15≤S / λ≤0.27, where λ is the average length the waves.  6. The antenna according to claim 5, characterized in that plate reflectors are introduced located on both sides of the extreme rhomboid sections and whose overall dimension in the orthogonal plane to the flat screen is made smaller than the distance S from the plane of the flat screen for the plane of the arrangement of the rhomboid sections.  7. The antenna according to claim 5, characterized in that a plate director is inserted symmetrically and parallel to the rhomboid sections, the maximum length of the plate director is chosen equal to the total length of the diagonals of the rhomboid sections along a common longitudinal axis, and the rhomboid sections are located between the flat screen and the plate director.

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