LOW-FREQUENCY FILTERING UNIT HAVING PATTERN WITH HIGH CONSISTENCY AND ANTENNA ARRAY

Abstract

A low-frequency filtering unit includes a vibrator arm, a balun base, a balun feeder line and a balun chamber tube for arranging the balun feeder line; the vibrator arm includes two radiation arms, one end of the radiation arm is vertically connected to one end of the other radiation arm to form an integral L-shaped right-angle structure, the balun chamber tube is arranged at the connection between the two radiation arms, and the wave-trap structures on the transverse radiation arm and the longitudinal radiation arm are symmetrically arranged with a 45? angular bisector of the L-shaped right-angle structure as a center line; the low-frequency filtering unit is provided with four vibrator arms which are symmetrically arranged in pairs around the periphery of the balun base along a diagonal line and form an integral cross orthogonal structure, and the vibrator arms.

Claims

1. A low-frequency filtering unit comprising a vibrator arm, a balun base, a balun feeder line and a balun chamber tube for arranging the balun feeder line, wherein the vibrator arm further comprising two radiation arms, and the two radiation arms further comprising a transverse radiation arm extending transversally and a longitudinal radiation arm extending longitudinally, wherein one end of the transverse radiation arm is vertically connected to one end of the longitudinal radiation arm to form an integral L-shaped right-angle structure, wherein the balun chamber tube is arranged at the connection between the transverse radiation arm and the longitudinal radiation arm, wherein the transverse radiation arm and the longitudinal radiation arm are provided with a wave-trap structure respectively, wherein the wave-trap structures on the transverse radiation arm and the longitudinal radiation arm are symmetrically arranged with a 45? angular bisector of the L-shaped right-angle structure as a center line; the low-frequency filtering unit is provided with four vibrator arms, wherein the four vibrator arms are symmetrically arranged in pairs around the periphery of the balun base along a diagonal line and form an integral cross orthogonal structure, and wherein the vibrator arms, the balun chamber tube, the balun feeder line and the balun base are all made of metal conductors.

2. The low-frequency filtering unit according to claim 1, wherein the rectangular L-shaped vibrator arm formed by the vertical connection of the two radiation arms comprising an inner L-shaped side edge and an outer L-shaped side edge, wherein the wave-trap structure comprising a hollow hole and a notch gap formed on the radiation arm, wherein one end of the notch gap is communicated with the hollow hole, and wherein the other end thereof extends from the hollow hole to the inner L-shaped side edge or the outer L-shaped side edge of the radiation arm.

3. The low-frequency filtering unit according to claim 1, wherein the vibrator arm is a plate-shaped metal conductor, and wherein the two radiation arms of the vibrator arm have downward folded edges at both ends in a width direction.

4. The low-frequency filtering unit according to claim 1, wherein the length and width of the two radiation arms of the vibrator arm are equal.

5. The low-frequency filtering unit according to claim 1, wherein a first gap is formed between two adjacent vibrator arms and a second gap is formed between two adjacent balun chamber tubes.

6. The low-frequency filtering unit according to claim 1, wherein the four vibrator arms, the balun base and the balun cavity tubes are integrally formed by die-casting technique.

7. An antenna array comprising a reflecting plate and the low-frequency filtering unit according to any one of claims 1 to 6, wherein the reflecting plate is provided with a plurality of high-frequency units and the low-frequency filtering unit, and the low-frequency filtering unit is arranged among the plurality of high-frequency units, and the position of the vibrator arm of the low-frequency filtering unit is higher than that of the high-frequency units.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0014] FIG. 1 is a three-dimensional schematic diagram of a low-frequency filtering unit having a pattern with high consistency in the present invention;

[0015] FIG. 2 is a local decomposition schematic diagram of the low-frequency filtering unit having the pattern with high consistency in the present invention:

[0016] FIG. 3 is a top view schematic diagram of the low-frequency filtering unit having the pattern with high consistency in the present invention:

[0017] FIG. 4 is an enlarged schematic diagram of a vibrator arm in the present invention:

[0018] FIG. 5 is an enlarged schematic diagram of the second embodiment of the vibrator arm in the present invention:

[0019] FIG. 6 is a layout schematic diagram of an antenna array in the present invention:

[0020] FIG. 7 is a schematic diagram of a wave-trap structure coupling current of the low-frequency filtering unit having the pattern with high consistency in the present invention under in the array layout:

[0021] FIG. 8 is a radiation pattern of the low-frequency filtering unit having the pattern with high consistency in the present invention:

[0022] FIG. 9 is a curve diagram of the gain and wave width of the low-frequency filtering unit having the pattern with high consistency varying along with the frequency in the present invention:

[0023] FIG. 10 is a schematic diagram of a high-frequency half-power beam width vibrated along with frequency when the conventional low-frequency unit and the low-frequency filtering unit having pattern with high consistency in the present invention are respectively arranged based on high-low-frequency arrays.

[0024] Numeral references: 100a refers to first vibrator arm, 100b refers to second vibrator arm, 100c refers to third vibrator arm, 100d refers to fourth vibrator arm, 110 refers to longitudinal radiation arm, 120 refers to transverse radiation arm, 130 refers to wave-trap structure, 131 refers to notch gap, 132 refers to hollow hole, 140 refers to connection between the transverse radiation arm and the longitudinal radiation arm, 150 refers to folded edge, 160 refers to L-shaped inner side edge, 170 refers to L-shaped outer side edge, 200 refers to balun chamber tube, 210a refers to balun feeder line, 210b refers to balun feeder line, 300 refers to balun base, 400 refers to high-frequency unit, 500 refers to reflecting plate, and 600 refers to strong coupling current.

DETAILED DESCRIPTION

[0025] As shown in FIG. 1 to FIG. 4, a low-frequency filtering unit having a pattern with high consistency comprises a vibrator arm, a balun base 300, a balun feeder line and a balun chamber tube 200 for arranging the balun feeder line, wherein the vibrator arm comprises two radiation arms, the two radiation arms comprises a transverse radiation arm 120 extending transversally and a longitudinal radiation arm 110 extending longitudinally, one end of the transverse radiation arm 120 is vertically connected to one end of the longitudinal radiation arm 110 to form an integral L-shaped right-angle structure, a connection 140 between the transverse radiation arm 120 and the longitudinal radiation arm 110 is provided with the balun chamber tube 200, and the transverse radiation arm 120 and the longitudinal radiation arm 110 are provided with a wave-trap structure 130 respectively, the wave-trap structures on the transverse radiation arm 120 and the longitudinal radiation arm 110 are symmetrically arranged with a 45? angular bisector of the L-shaped right-angle structure as a center line, therefore, the wave-trap structures on the transverse radiation arm 120 and wave-trap structures on the longitudinal radiation arm 110 have the same number and are in the same shape and size: the low-frequency filtering unit is provided with four vibrator arms, wherein the four vibrator arms refers to a first vibrator arm 100a, a second vibrator arm 100b, a third vibrator arm 100c and a fourth vibrator arm 100d, the four vibrator arms are symmetrically arranged in pairs around the periphery of the balun base 300 along a diagonal line and form an integral cross orthogonal structure. In the embodiment, the first vibrator arm 100a and the third vibrator arm 100c are symmetric along the diagonal line, the second vibrator arm 100b and the fourth vibrator arm 100d are symmetric along the diagonal line, and the four vibrator arms, the balun chamber tube 200, the balun feeder line and the balun base 300 are all made of metal conductors.

[0026] The low-frequency filtering unit having the pattern with high consistency in the present invention can arrange the balun feeder line according to the actual feeding mode. The embodiment uses a balun direct feeding mode, as shown in FIG. 2. The balun feeder line 210a is arranged in the balun chamber tube connected to the first vibrator arm 100a, and the balun feeder line 210b is arranged in the balun chamber tube connected to the second vibrator arm 100b; the balun feeder line 210a excites a low-frequency vibrator comprising the first vibrator arm 100a and the third vibrator arm 100c to form +45? polarization; the balun feeder line 210b excites a low-frequency vibrator comprising the second vibrator arm 100b and the fourth vibrator arm 100d, forming ?45? polarization. If a coupling feeding mode is adopted, the balun chamber tubes of the four vibrator arms are provided with the balun feeder line inside respectively.

[0027] The vibrator arm with the L-shaped right-angle structure formed by the vertically connecting the two radiation arms, namely the transverse radiation arm 120 and the longitudinal radiation arm 110, has an L-shaped inner side edge 160 and an L-shaped outer side edge 170. The wave-trap structure 130 comprises a hollow hole 132 and a notch gap 131 formed on the radiation arm. One end of the notch gap 131 is communicated with the hollow hole 132, and the other end of the notch gap 131 extends from the hollow hole 132 to the L-shaped inner side edge 160 of the radiation arm or to the L-shaped outer side edge 170 of the radiation arm. In the embodiment, the notch gap 131 extends from the hollow hole 132 to the L-shaped inner side edge 160 of the radiation arm. The shape of the hollow hole 132 may be regular or irregular polygons, such as square, rectangle, diamond, pentagon, hexagon, etc., and the hollow hole 132 may also be circular or elliptical. The number of wave-trap structures on each radiation arm of the vibrator arm may be one or more. In the embodiment, each of the two radiation arms are provided with two wave-trap structures, wherein the two wave-trap structures on the transverse radiation arm 120 are the wave-trap structure 130a and the wave-trap structure 130b respectively, and the two wave-trap structures on the longitudinal radiation arm 110 are the wave-trap structure 130c and the wave-trap structure 130d respectively, while the wave-trap structure 130a and wave-trap structure 130d, the wave-trap structure 130b and the wave-trap structure 130c are axially symmetrical with the 45? angular bisector of the transverse radiation arm 120 and the longitudinal radiation arm 110 as the center line. As shown in FIG. 4, the hollow hole 132 of the wave-trap structure 130 in the embodiment is elliptical. FIG. 5 shows another embodiment of the wave-trap structure 130, and the hollow hole 132 is rectangular.

[0028] As a preferred technical solution, the vibrator arms are all plate-shaped metal conductors, and the two radiation arms of the vibrator arm, namely the transverse radiation arm 120 and the longitudinal radiation arm 110, have downward folded edges 150 at both ends of the respective width directions; and the setting of folded edges 150 may play an effective role in strengthening the structural intensity of the vibrator arm.

[0029] As a further preferred technical solution, the length and width of the two radiation arms forming the vibrator arm 100 are equal: gaps exist between the two adjacent vibrator arms and between the balun chamber tubes.

[0030] See FIG. 6, an antenna array comprises a reflecting plate 500. The reflecting plate 500 is provided with a plurality of high-frequency units 400 and low-frequency filtering units having the pattern with high consistency. The low-frequency filtering units having the pattern with high consistency are arranged among the plurality of high-frequency units 400, and the position of the vibrator arm of the low-frequency filtering unit is higher than the high-frequency units 400. In this environment, the size of the wave-trap structure 130 on the vibrator arm is influenced by the model selection of the high-frequency unit 400, the position relationship between the high-frequency unit and the low-frequency unit, the operating frequency and other factors.

[0031] FIG. 7 is a schematic diagram of the coupling current 600 of the wave-trap structure 130 in the above environment. In the antenna array co-arrayed with the high-frequency unit 400, an electric field generated by the excitation of the high-frequency unit 400 is upward, and the coupling current 600 is generated by the coupling of the low-frequency vibrator, leading to the distortion of the pattern. The low-frequency filtering unit having the pattern with high consistency is in the direction of the electric field of the high-frequency unit 400. As the strong coupling current 600 generated by the metal gap 131 forms a loop through the edge of the metal hollow 312, the coupling current 600 has the same intensity and opposite direction, so as to offset each other.

[0032] The low-frequency filtering unit having the pattern with high consistency in the present invention is designed and verified via CST. FIG. 8 shows a radiation pattern from 690 MHz to 960 MHz of the low-frequency filtering unit having the pattern with high consistency in the present invention through CST simulation. The results show that the pattern has high consistency. It can be seen from the curve diagram (FIG. 9) of the gain and wave width of the low-frequency filtering unit having the pattern with high consistency varying along with the frequency in the present invention that the gain 710 of the low-frequency filtering unit having the pattern with high consistency is 7.93 dBi?0.08 dBi, and the half-power beam width 720 is 75.4??1.1?, which has highly consistent radiation pattern characteristics in the wide frequency band (690 MHz-960 MHz), and has significant improvement on the problem of inconsistent signal coverage caused by different frequencies.

[0033] In addition, in the array environment as shown in FIG. 6, when the existing low-frequency unit without the wave-trap structure and the low-frequency filtering unit having the pattern with high consistency in the present invention are respectively arranged among the high-frequency unit 400 arrays, the variation of the horizontal half-power beam width of the high-frequency unit 400 array along with the frequency is shown in FIG. 8. When the low-frequency unit is an existing unit without the wave-trap structure, it can be seen from a curve 810 of the high-frequency half-power beam width varying with frequency that the beam is deformed due to the coupling of high and low frequencies, resulting in significant changes in the high-frequency horizontal half-power beam width since 2100 MHz. While adopting the low-frequency filtering unit having the pattern with high consistency in the present invention, it can be seen from a curve 820 of the high-frequency half-wave beam width varying with frequency that the abrupt change of wave width caused by the high-low frequency coupling is improved.

[0034] The technology involved in the low-frequency filtering unit having the pattern with high consistency in the present invention may effectively improve the pattern consistency of the low-frequency unit, and effectively improve the influence of the low-frequency unit on the high-frequency beam in the process of high-low frequency array formation, and as the structure is easy to achieve, die-cast integrated molding may be adopted, which has a lower cost than the design scheme of the branch filtering and LC filtering circuit, etc., and thus it can be widely used in the field of mobile communication antenna.

[0035] The specific implementation of the present invention is described in detail above, but the content is only a preferred implementation scheme of the prevent invention and cannot be considered to limit the implementation scope of the present invention. All equal vibrations and improvements made according to the application scope of the present invention shall still fall within the scope of the patent of the present invention.