Thin-substrate phase amplitude correction slot line difference beam planar horn antenna

Abstract

The invention discloses a thin-substrate phase amplitude correction slot line difference beam planar horn antenna, and relates to a horn antenna. The thin-substrate phase amplitude correction slot line difference beam planar horn antenna comprises a micro-strip feeder (2), a horn antenna body (3) and slot line horns (4), wherein the micro-strip feeder (2), the horn antenna body (3) and the slot line horns (4) are arranged on a dielectric substrate (1), the horn antenna body (3) comprises a first metal plane (7), a second metal plane (8) and two metallization through hole horn side walls (9), the horn antenna body (3) is provided with an odd number of metallization through hole arrays (11), and an even number of dielectric-loaded waveguides (15), the widths of the dielectric-loaded waveguides (15) on an aperture surface (10) of the horn antenna body (3) are equal, each dielectric-loaded waveguide (15) is connected with the slot line horns (4), a left-half antenna (13) and a right-half antenna (14) are arranged symmetrically, and the slot line horns (4) connected with the left-half antenna (13) and the slot line horns (4) connected with the right-half antenna (14) are arranged symmetrically. Electromagnetic waves can reach the slot line horns in an equal-amplitude and in-phase mode and then carry out radiation, and the direction of polarization of a radiation field is parallel to the dielectric substrate; the thin-substrate phase amplitude correction slot line difference beam planar horn antenna can be manufactured with the thin substrate, and is high in gain, large in zero drawdown, low in cost and compact in structure.

Description

technical field [0001] The invention relates to a horn antenna, in particular to a planar horn antenna with thin substrate phase amplitude correction groove line difference beam. Background technique [0002] Horn antennas are widely used in systems such as satellite communications, ground microwave links, and radio telescopes. However, the huge geometric size of the three-dimensional horn antenna restricts its application and development in planar circuits. In recent years, the proposal and development of substrate-integrated waveguide technology have greatly promoted the development of planar horn antennas. The substrate-integrated waveguide has the advantages of small size, light weight, easy integration and fabrication. The planar substrate-integrated waveguide horn antenna based on the planar substrate-integrated waveguide not only has the characteristics of the horn antenna, but also realizes the miniaturization and light weight of the horn antenna, and is easy to ...

AI Technical Summary

Problems solved by technology

In addition, the gain of the traditional substrate-integrated waveguide planar horn antenna is relatively low. The reason is that due to the continuous opening of the horn mouth, the phase is not synchronized when the electromagnetic wave propagates to the horn aperture surface, and the amplitude distribution of the aperture electric field intensity is not uniform. The radiation directivity and gain are reduced, making the zero depth of the formed differential beam antenna shallower and the slope lower, which affects the direction finding accuracy of the radar

At present, methods such as dielectric loading and dielectric prisms have been used to correct the horn aperture field, but these methods can only improve the consistency of the phase distribution, but cannot improve the uniformity of the amplitude distribution, and these phase calibration structures increase the overall structural size of the antenna

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