Printed impedance transformer for broadband dual-polarized antenna

Abstract

A broadband dual-polarized antenna integrated high-performance balun. The antenna structure consists of three main parts: radiator, feeding structure and reflector. The radiation element consists of four radiation parts with petal shape, forming two pairs of orthogonal dipole antennas. The feeding structure consists of four circuit boards with separated lines, forming resonant structures corresponding to a balance transformer. The reflector enables to direct the beam, increasing the antenna's orientation.

Claims

1. Broadband dual-polarized antenna with a impedance transformer integrated balun structure, comprising: a radiating element consisting of four copper plates which have the same petal shape and size, the copper plates are symmetrical and composed of two pairs of orthogonal dipole antennas, wherein the four copper plates are printed on a 0.508 mm thickness substrate made of rogers duroid 5880 material with a dielectric constant of 2.2 and a loss tangent of 0.0009; a feeding structure that consists of four stem boards made of RO4350B, with a dielectric constant of 3.48 and a loss tangent of 0.0037; wherein the four stem boards comprise copper lines printed on two sides of each board; the four stem boards and the radiating element are linked together by welds between the copper plates and the copper lines on the outer side of the each stem boards; wherein the feeding structure acts as a balance transformer, where the performance of the balance transformer is characterized by the shape and size of the copper lines printed on the four stem boards; and a reflector comprising a copper plate on a reflector substrate, the reflector's structure is a square with four mid-slits cut just enough for the feeding structure to pass; the reflector helps the antenna to focus radiant energy in a direction perpendicular to the reflector, so the antenna will have a higher gain.

2. A broadband dual-polarized antennas with a high-performance balun comprising: each of a pair of radiators welded to an outside of corresponding stem boards, forming a resonant structure in a form of a parallel two-plane waveguide short-circuited at a terminal; copper lines being on an inside of two orthogonal pair of the stem boards combined with conducting lines located on planes of a radiator substrate form a resonant gamma-shaped structure; these two resonant structures combine through mutuality, converting a balanced signal on each pair of radiators to an unbalanced signal at an antenna output.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 illustrates the side view of the antenna;

(2) FIG. 2 illustrates the top view of the radiator;

(3) FIG. 3 illustrates a one-sided antenna structure of a contacted antenna;

(4) FIG. 4 illustrates the side view of the balun;

(5) FIG. 5 is the result of reflector coefficient;

(6) FIG. 6 shows the radiation pattern of the proposed antenna.

DETAILED DESCRIPTION

(7) The proposed antenna has the following structure: radiator (1), the integrated balun (2), reflector (3). Additionally, there are also a number of auxiliary components such as dielectric substrates (4), (5), circuit line (6) and outer side of the circuit board (7).

(8) The radiating structure of the antenna shown in FIG. 2 consists of four identical, petal-shaped thin metal plates lying symmetrically across two orthogonal axes and a center of symmetry. The two opposite metal plates form a dipole antenna. Radiator (1) has the shape of a four-petals flower, the corners of the radiator are cut in a rounded shape. The structure of the radiator is curves creating multiple half-wavelength resonance segments to expand the bandwidth.

(9) Radiator (1) is printed on substrate (4) which is Rogers material RT5880 due to this material has low relative permittivity and low loss tangent. In addition, the thickness of the substrate of the antenna should be thin to reduce the dielectric loss.

(10) Radiator (1) is mounted above the ground with the height of a quarter of wavelength referring to the center frequency of the operating band. This reflector is printed on a dielectric substrate (5).

(11) In the FIG. 3, the feeding structure consists of four stem boards, in which the copper lines (6) are printed on two sides of each board. The structure that combines the microstrip lines and the radiator forms a balance transformer. Each pair of radiator wings is welded with the outer surface of the corresponding stem board. They become a resonant structure in the form of a parallel two-plane waveguide that is short-circuited at the terminal. The microstrip line on the inside of the circuit board combined with the conducting line located on the radiator plane forms a resonant Γ-shaped structure. The two resonant structures combine through mutuality, converting a balanced signal on each pair of radiators to an unbalanced signal at the antenna output.

(12) The structure and dimensions of the balun are showed in FIGS. 3 and 4. The transmission line is designed on a microstrip circuit printed on the RO4350B substrate with a dielectric constant of ε.sub.r=3.48, loss tangent of 0.0037 and the thickness of 30 mils. With the transmission structure in the present invention, the line size corresponding to the 50Ω impedance is w.sub.2=0.9 mm. An impedance matching line of length h.sub.2=13.2 mm coordinates the impedance from a position with 100Ω to the position with 50Ω impedance. The line width at the 100Ω impedance position is w.sub.1=0.5 mm. Dimensions of the feeding part are listed detail in Table 1.

(13) TABLE-US-00001 TABLE 1 Dimensions of the Γ-shaped balun. Dimensions of the Γ-shaped balun (unit: mm) w.sub.1 w.sub.2 w.sub.3 h.sub.1 h.sub.2 h.sub.3 l.sub.1 l.sub.2 1.8 0.5 0.4 5 13.2 3 5.2 6.3

(14) Reflector (3) is structured as a square cut with 4 slots in the middle, just enough for the balun (2) to pass through. Reflector (3) allows the antenna to focus radiant energy in a direction perpendicular to the reflector, so the antenna will have a high gain.

(15) As simultaneously fed by two ports, the antennas operate in two polarizations orthogonal to each other. By feeding in pairs, the signal on copper line (6) has the same phase and amplitude. The antenna, therefore, does not need additional phase compensation, reducing the complexity and equipment of the antenna system.

Execution Example

(16) FIG. 5 shows the reflector coefficient in the operating frequency range 4-8 GHz. The reflector coefficient is the ratio of the incident power to the reflected power when an antenna is fed at a particular port. As shown in FIG. 5, the reflector coefficient is lower than −10 dB over the operating frequency range. A low reflection coefficient indicates a good level of impedance matching between the radiator and feeding structure.

(17) FIG. 6 illustrates the radiation pattern of the antenna in the E-plane and H-plane at 6 GHz. Radiation pattern refers to the directional (angular) dependence of the strength of the radio waves from the antenna. The antennas, which are applied for the spectrum surveillance system, have a large open angle on the radiation pattern to be able to receive signals over a wide region. Realizing that the opening angle at the half-power level is 72 degrees, which is relatively large to ensure wide-angle reception and transmission.