SU1665438A1 - Device for electronic scanning of beam of shf electromagnetic wave - Google Patents

Abstract

The invention relates to radar technology and can be used in various radio systems of the millimeter and submillimeter wavelengths. The purpose of the invention is to provide the ability to scan the beam by two coordinates in the aperture plane and to increase the speed. The device contains a source of microwave radiation 1, rectangular dielectric waveguides 2 and 3 with beveled end faces, connected by ends with rotation by 90 °, one-dimensional polarization wire gratings 4, which are coated with a ferroelectric coating. When applying control voltage to one-dimensional polarization wire gratings 4, the beam is scanned at two coordinates in the aperture plane with a speed reaching 10 ⁷ Hz. 2 Il.

Description

1

The invention relates to radar technology and 6 different millimeter and submillimeter wavelength radio systems can be used.

The purpose of the invention is to provide two-coordinate scanning capability in the aperture plane and to increase the speed.

Figure 1 shows the block diagram of a device for electronically scanning a beam of an electromagnetic microwave wave; Fig. 2 shows the construction of a rectangular dielectric waveguide.

The device for electron beam scanning of an electromagnetic microwave wave contains a source of microwave radiation 1, rectangular dielectric waveguides 2 and 3, one-dimensional polarization wire gratings 4, ferroelectric coatings 5, dielectric b and Control voltage terminals 7.

The wires of one-dimensional polarized wire gratings are perpendicular to the plane of polarization of the linearly polarized microwave wave, interconnected, and the distance between them is 0.05 of the working wavelength.

A device for electronically scanning a beam of an electromagnetic microwave wave operates as follows.

A beam of electromagnetic microwave waves from microwave source 1 is directed normally to the beveled face of the first rectangular dielectric waveguide 2. The angle between the end face and the base of the waveguide creates more critical so that when reflected from the base of the waveguide there is always a condition of total internal reflection. The dielectric 6 transmitted by the wave is reflected from the bases of the first rectangular dielectric waveguide 2 and when the voltage is applied to the control voltage terminals 7 leading to a change in the dielectric constant of the ferroelectric coating 5, the beam is displaced in the plane of the output end of the first rectangular dielectric waveguide 2 The beam enters a similarly controlled rectangular dielectric waveguide 3, where the beam is shifted in an orthogonal plane.

The use of zero-inertia ferroelectric coatings allows to increase the speed to 107 Hz.

Thus, providing scanning of the electromagnetic microwave beam in the entire plane of the aperture of the device for electron scanning of the electromagnetic microwave beam.

Claims (1)

Invention Formula A device for electronically scanning a beam of an electromagnetic microwave wave, containing a source of microwave radiation and the first rectangular dielectric waveguide, whose faces are made obliquely, on one of the bases of which a metallic grid of conductors is arranged, which are located perpendicular to the plane of polarization of a linearly polarized microwave wave, characterized in that, in order to provide the ability to scan the beam in two coordinates in the plane of the aperture and increase speed, introduced a second rectangular dielectric waveguide, similar to the first rectangular dielectric waveguide, connected at the end with the first rectangular dielectric waveguide and deployed relative to the plane of the end of the first rectangular dielectric waveguide by 90 ° metal gratings located on the first and second rectangular dielectric waveguides are made in the form of one-dimensional polaris tional wire grids, wires that are interlaced and connected to the control voltage terminals, ferroelectric coatings are applied to the metal grids, and the end faces of the first and second rectangular dielectric waveguides form an angle more critical than the base of the waveguides and are oriented perpendicular to the input and output beams . FIG. I