RU2316857C1 - Device for transforming electromagnetic wave polarization - Google Patents

Abstract

FIELD: antenna engineering.

SUBSTANCE: proposed device has radio-transparent insulating layer and helical components forming lattice structure which are equally spaced apart therein. Axes of all helical components are positioned unidirectionally and lie in insulating layer plane; axis and ends of each helical component form plane perpendicular to direction of reflected wave propagation. Each helical component has following characteristics: N_t turns and helix pitch angle α found from formula

where α is angle of helix pitch angle; N_t is turn number of helical component. Length of conductor forming helical component equals half the length of electromagnetic wave.

EFFECT: ability of transforming linearly polarized electromagnetic wave into circularly polarized wave irrespective of plane position of incident linearly polarized electromagnetic wave at desired direction of incident wave propagation.

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Description

The invention relates to antenna technology, in particular for converting a linearly polarized electromagnetic wave into an electromagnetic wave with circular polarization, and can be used, for example, to transmit signals with circular polarization in the microwave range in space communication systems.

The current level of technology is characterized by a number of devices capable of solving this problem in various areas of wavelengths.

From optics, a classical device for producing a circularly polarized wave made in the form of a crystal plate cut parallel to the optical axis is known, and the plate thickness is such that the optical path difference of the two rays passing through the plate, whose light vector oscillations occur in mutually perpendicular directions , is a quarter of the wavelength of the incident radiation [1].

In this case, the amplitudes of oscillations of mutually perpendicular waves should be equal. Equality of amplitudes is achieved by dropping a linearly polarized electromagnetic wave onto the plate at a quarter wave so that the direction of oscillation of its light vector is at an angle of 45 ° with the direction of the optical axis of the plate.

This device operates mainly in the optical range, works only when a wave passes through the device, and functions only with a certain direction of oscillation of the light vector.

Closest to the technical nature of the claimed is a device for converting the polarization of an electromagnetic wave containing a dielectric layer with a lattice structure made of the same conductive elements [2].

In this case, the dielectric layer is a board, on one side of which a lattice structure is made of identical conductive elements, which are meander lines located at an angle of 45 ° to the plane of linear polarization of the electromagnetic wave and parallel to each other.

In addition, the lattice structure has parameters that provide a phase change of two components of the vector of the electric field strength of the electromagnetic wave passing through the antenna polarizer.

The principle of operation of the known device is based on the orientation of the plane of linear polarization of the incident electromagnetic wave, which significantly narrows the scope of its application. The known device provides a wave with circular polarization only when the electromagnetic wave passes through the device, which makes it impossible to use it in reflective systems.

In addition, the manufacturing process of the lattice structure is chemical, in accordance with the technology for manufacturing printed circuit boards, which is quite time-consuming.

The technical problem solved by the claimed invention is to create a device for converting the polarization of an electromagnetic wave from linear to circular, regardless of the orientation of the plane of linear polarization of the incident electromagnetic wave for a given direction of propagation of the incident wave.

The technical result achieved by the implementation of the claimed invention:

- the formation of a circularly polarized wave occurs due to the radiation of interconnected electric dipole moment and magnetic moment of each spiral element, which give equal in absolute value contributions to the reflected wave;

- simplification of the manufacturing process of the lattice structure.

The technical result is achieved in that in a device for converting the polarization of an electromagnetic wave containing a dielectric layer with a lattice structure made of the same conductive elements, the conductive elements are made in the form of spiral elements placed in the dielectric layer, so that the axes of the spiral elements are oriented in one direction and lie in the plane of the dielectric layer, and the axis and ends of each spiral element form a plane perpendicular to the direction of propagation of the reflection wave, with each spiral element has a number N _in turns and an angle α of rise of turns, which is determined by the formula

where α is the angle of elevation of the turns of the spiral element,

N _in - the number of turns of the spiral element.

In addition, the length of the conductor from which the spiral element is made is equal to half the length of the electromagnetic wave.

In addition, the dielectric layer is radiolucent.

The invention consists in the following.

In accordance with the theory of electromagnetic field interactions described in [3], the components of the electric dipole moment (p) and magnetic moment (m) directed along the axis of the spiral element play the main role in the emission of a circularly polarized electromagnetic wave. The parameters of the spiral elements, namely, the number N _{in the} turns of the spiral element, the angle α of rise of the turns of the spiral element, the length L of the conductor from which the spiral element is made, are designed so that the formation of a circularly polarized wave occurs only due to the emission of these components. Moreover, the components of the moments orthogonal to the axes of the spiral elements can only have a distorting effect on the radiation of a circularly polarized wave, and their effect should be minimized. For this, the plane passing through the axis and ends of each spiral element is oriented at an angle of 90 ° to the direction of propagation of the reflected wave, because in this configuration, due to the symmetry of the current distribution along the spiral element, the components of the electric dipole and magnetic moments perpendicular to the axis of the spiral element and the direction of propagation of the reflected wave are equal to zero and cannot distort the radiation of a circularly polarized wave. The components of the electric dipole and magnetic moments parallel to the direction of propagation of the reflected wave do not contribute to the reflected wave and do not distort its circular polarization.

In order for the formation of a circularly polarized reflected wave, the angle α of rise of the turns of the spiral element is determined by the theoretically calculated formula:

where α is the angle of elevation of the turns of the spiral element,

N _in - the number of turns of the spiral element.

This formula was obtained by applying the dipole approximation when considering the radiation of a spiral element under the condition of the main frequency resonance and provided that the electric dipole moment and the magnetic moment of the spiral element make equal contributions to the reflected wave in absolute value, as a result of which this wave acquires circular polarization.

The length of the conductor from which the spiral elements are made is calculated from the condition of the main frequency resonance, from which it follows that the current in the conductor reaches its maximum value when the conductor length L is equal to half the electromagnetic wavelength, i.e.

where L is the length of the conductor,

λ is the wavelength of the working range in vacuum.

The calculated elevation angle α of the turns of the spiral element uniquely determines the radius r of the coil of the spiral element and the step h of the spiral element, depending on the number N _{in the} turns of the spiral element:

where r is the radius of the coil of the spiral element,

h is the pitch of the spiral element,

L is the length of the conductor,

α is the angle of elevation of the turns of the spiral element,

N _in - the number of turns of the spiral element.

A comparative analysis of the proposed solution with the prototype shows that the claimed device differs from the known geometric shape of the conductive elements, the relationship of the parameters and their location in the dielectric layer, namely, regardless of the orientation of the plane of linear polarization of the incident electromagnetic wave.

Thus, the inventive device for converting the polarization of an electromagnetic wave is new.

An analysis of the scientific, technical and patent literature of the current state of the art in this area has revealed the widespread use of the feature “spiral element, namely a cylindrical spiral” in cylindrical helical antennas of axial radiation (see Antennas and microwave devices. Calculation and design of antenna arrays and radiating elements. Under Edited by Professor D.I. Voskresensky, Moscow: Soviet Radio, 1972, p.241, AS USSR No. 1246196, class H01Q 11/88, published July 23, 86, AS USSR No. 1626294, CL H01Q 3/24, published on February 7, 1992).

Known helical helical antennas containing a reflective shield and a conductive single-helical cylindrical helix (or coils) located above it, connected to the feeder, differ only in the design parameters of the active helixes and their relative position relative to each other and their general position relative to the reflective screen. In known devices, the axial radiation mode with elliptical polarization of radiation is implemented. In the inventive device, the spiral element is passive, in contrast to the known ones, and ensures the achievement of a different technical result, namely, the formation of a circularly polarized wave in the direction perpendicular to the axial, due to radiation of equal in magnitude and related components of the electric dipole and magnetic moments .

The presence of the use of the feature was also revealed - an antenna array of cylindrical spirals (see patent RB No. 4062, class H01Q 21/24, publ. 2001.09.30).

The known antenna array contains active cylindrical spirals with opposite windings of the turns from the conductor and identical winding angles of at least 14 degrees, the number of turns equal to at least three, and a flat reflective screen, and the active spirals are located above the reflective screen and perpendicular to it by their axes, and each active spiral has a power input on the screen side.

The known device is intended to produce linearly polarized radiation. In the inventive device, the lattice structure is made of the same conductive elements in the form of passive, in contrast to the known spiral elements and, in combination with other signs, achieves a different technical result, namely, the formation of a circularly polarized wave.

The analysis of scientific, technical and patent information did not reveal in the known technical solutions of the claimed combination of essential features and the invention does not explicitly follow from the prior art, which allows us to conclude that the claimed device for converting the polarization of an electromagnetic wave has an inventive step.

The inventive device for the conversion of polarization is industrially applicable, since if it is used, it is possible to realize the specified destination.

Figure 1 schematically shows the inventive device for converting polarization.

Figure 2 - spiral element.

Figure 3 - spiral element in expanded form.

The inventive device for converting the polarization of an electromagnetic wave contains a radio-transparent dielectric layer 1 (see figure 1) and spiral elements 2 forming a lattice structure. In the manufacture of the device, the spiral elements 2 are arranged from each other, so that the axes 3 of all spiral elements 2 are oriented in the same direction and lie in the plane of the dielectric layer 1, and the axis 3 and the ends of each spiral element 2 form a plane perpendicular to the direction of propagation of the reflected wave . The spiral elements 2 are poured with a radiolucent dielectric material and allowed to solidify, or inserted into parallel grooves in a solid radiolucent dielectric layer 1. Each spiral element (see Fig. 2) is made with the following parameters: has a number N _in turns, the angle α of the turn of the turns, the radius r turn, step h and the length L of the conductor (see figure 3).

A device was made for converting an incident linearly polarized electromagnetic wave into an circularly polarized electromagnetic wave. A foam was used as a radiolucent dielectric layer. The lattice parameters were calculated for a frequency of 3 GHz. The lattice structure is made of identical copper spiral elements with the number N _in = 2 turns; angle α = 7.1 ° of the rise of the turns; length L = 0.05 m of the conductor; radius r = 3.95 × 10 ^-3 m of turn; pitch h = 3.1 × 10 ^-3 m.

To measure the polarization characteristic, a method based on the use of a receiving antenna with linear polarization of the field (horn antenna) was used.

A horn antenna emits a linearly polarized electromagnetic wave. The radiation reflected by the device is examined in a direction perpendicular to the plane passing through the axis and ends of each spiral element.

The test results are shown in the graph (figure 4), illustrating the dependence of the ellipticity coefficient on the frequency of the incident electromagnetic wave. In the region of the resonant frequency of 3 GHz, the device provides an electromagnetic wave with circular polarization, with an ellipticity coefficient close to unity (about 0.98).

Information sources

1. G.S. Landsberg. Optics. M .: Nauka, 1976.928 s.

2. A.S. USSR No. 1821853 A1, H01Q 15/00, publ. 1993 (prototype).

3. L.D. Landau, E.M. Lifshits. Field theory. M .: Nauka, 1973.V.2. 504 s.

Claims (3)

1. Device for converting the polarization of an electromagnetic wave containing a dielectric layer with a lattice structure made of the same conductive elements, characterized in that the conductive elements are made in the form of spirals placed in the dielectric layer so that the axes of the spiral elements are oriented in one direction and lie in the plane of the dielectric layer, and the axis and ends of each spiral element form a plane perpendicular to the direction of propagation of the reflected wave, with each spiral th element has N _in turns and a lifting angle α, which is determined by the formula

where α is the angle of elevation of the spiral element, N _in - the number of turns of the spiral element. 2. The device according to claim 1, characterized in that the length of the conductor from which the spiral element is made is equal to half the length of the electromagnetic wave. 3. The device according to claim 1, characterized in that the dielectric layer is radiolucent.

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