WO2022012022A1 - Low-profile radiation unit and small base station antenna - Google Patents

Abstract

The present invention provides a low-profile radiation unit, comprising a dielectric substrate, a radiator and a feeding balun, the radiator comprising two orthogonally distributed dipoles which are respectively provided in ±45°C directions of the dielectric substrate; and the feeding balun being of an orthogonal structure, the bottom of the feeding baluns being connected to a feeding network, and the top of the feeding baluns being connected to the radiator, and being used for feeding each of the dipoles by means of a feeding probe in a coupling manner. The present invention further provides a small base station antenna containing the low-profile radiation unit. In this way, the present invention can achieve a design of wide-frequency band and low-profile of the radiation unit while ensuring antenna performance, thereby achieving the purpose of miniaturizing the antenna.

Description

Low Profile Radiating Elements and Small Base Station Antennas technical field

The present invention relates to the technical field of wireless communication, and in particular, to a low-profile radiation unit and a small base station antenna.

Background technique

The base station is the air interface connecting the user and the network in the mobile communication system, so it is one of the most critical components of the system, which directly determines the coverage of the mobile communication network and the quality of signal transmission. Base stations can be divided into outdoor large-scale macro base station antennas and small base station antennas according to application scenarios; macro base station antennas are characterized by a wide frequency band, a large number of radiating elements, high gain, and large power capacity, and are suitable for large-scale and sparse user scenarios. The characteristics of small base station antennas are narrow frequency band, fewer radiation units, low gain, and small power capacity, and are suitable for local blind coverage or coverage in areas with dense users.

With the development of wireless communications, users' demands for high-speed data services continue to increase, and most data communications are performed indoors. However, it is difficult to build a macro base station to meet the needs of a large number of users, and the coverage depth of the macro base station is not enough, especially at the edge of the cell, the signal strength is significantly weakened, the link signal-to-noise ratio is reduced, and the user experience is degraded. Small base station antennas can be regarded as a small version of macro base station antennas that are introduced into buildings for intensive deployment. In this context, the development of small base station antennas is necessary and important.

As one of the key components of the base station antenna, the radiating unit plays a vital role in the entire mobile communication network. In the prior art, the radiating element of the antenna generally realizes the feeding of the feeding balun to the vibrator by welding the feeding sheet, which has the disadvantages of complex structure and high cost of the radiating element. Under the current limited antenna surface resources, the antenna puts forward higher requirements for the size of the radiating element. Usually, the size of the radiating element should be reduced as much as possible while ensuring the performance of the antenna. In order to strictly control the weight and size of the antenna, the base station The miniaturized design of the antenna has become the mainstream trend of the current industry development.

To sum up, the prior art obviously has inconvenience and defects in practical use, so it is necessary to improve it.

SUMMARY OF THE INVENTION

In view of the above-mentioned defects, the purpose of the present invention is to provide a low-profile radiating element and a small base station antenna, which can realize the broadband and low-profile design of the radiating element while ensuring the antenna performance, thereby achieving the purpose of miniaturizing the size of the antenna.

In order to achieve the above object, the present invention provides a low-profile radiating unit, comprising a dielectric substrate, a radiator and a feeding balun; the radiator includes two orthogonally distributed dipoles, respectively at ±45° of the dielectric substrate distributed and placed in the direction; the feed balun is in an orthogonal structure, the bottom of the feed balun is connected to the feed network, the top of the feed balun is connected to the radiator, and the feed probe passes through The coupling feeds each of the dipoles.

According to the low-profile radiating unit of the present invention, the radiator is composed of four radiating arms, and the radiating arms are in the shape of leaves.

According to the low-profile radiation unit of the present invention, the radiating surface of the radiator has an aperture side length of 0.3-0.35λ; and/or

The current path of the radiation arm is 0.25λ;

The λ is the wavelength of the working frequency band of the low-profile radiation unit.

According to the low profile radiating element of the present invention, the impedance characteristic of the feeding balun is optimized through impedance matching.

The low-profile radiation unit according to the present invention further includes a grounding plate;

The feeding balun is composed of two orthogonally combined circuit boards, each of the circuit boards includes a dielectric sheet, and the front surface of the dielectric sheet is distributed with feeding lines that are bent and deformed. The back is covered with ground; the bottom of the feed line is connected to the feed network, the bottom of the ground of the feed line is connected to the ground plate, and the top of the ground is connected to the radiator power feed.

According to the low-profile radiation unit of the present invention, the length of the feed balun is 0.125λ; the λ is the wavelength of the operating frequency band of the low-profile radiation unit.

According to the low-profile radiation unit of the present invention, the circuit board includes a first circuit board and a second circuit board, the first circuit board is provided with a first fitting groove, and the second circuit board is provided with a first fitting groove. a second fitting groove; the first circuit board and the second circuit board are respectively fitted into an orthogonal structure through the first fitting groove and the second fitting groove.

According to the low-profile radiation unit of the present invention, the top of the first circuit board is provided with at least two first upper fins, and the top of the second circuit board is provided with at least two second upper fins, so The radiator is correspondingly provided with at least four upper slots, and the first circuit board and the second circuit board are respectively clamped to the radiator through the first upper protrusion and the second upper protrusion. the upper slot of the body;

The bottom of the first circuit board is provided with at least two first lower tabs; the bottom of the second circuit board is provided with at least two second lower tabs, and the grounding sheet is correspondingly provided with at least four lower openings The first circuit board and the second circuit board are respectively clamped to the lower slot of the grounding sheet through the first lower tab and the second lower tab.

The present invention also provides a small base station antenna, which includes a reflector, and a plurality of low-profile radiation units according to any one of the above are distributed on the reflector.

According to the small base station antenna of the present invention, a plurality of the low-profile radiating elements form at least one line array and are distributed on the reflector, and the spacing between the adjacent low-profile radiating elements is 0.8-1λ. The λ is the wavelength of the working frequency band of the low-profile radiation unit.

The low-profile radiation unit of the present invention includes a dielectric substrate, a radiator and a feeding balun. The radiator includes two orthogonally distributed dipoles, which are respectively distributed and placed in the ±45° direction of the dielectric substrate to form a dual-polarized radiation unit. . The feeding balun is in an orthogonal structure, and the top of the feeding balun is connected to the radiator, and each dipole is fed by coupling through the feeding probe. In this way, the present invention adopts the method of coupling feeding and the form of deforming feeding balun to reduce the profile of the radiation unit, which can realize the broadband and low profile design of the radiation unit while ensuring the performance of the antenna, so as to achieve the purpose of miniaturizing the size of the antenna. . Preferably, the radiator is composed of four leaf-shaped radiation arms, and the leaf-shaped circuit can make the radiation unit meet the electrical size required for excitation under a small diameter, and can further reduce the cross-section of the radiation unit. More preferably, the impedance characteristic of the feeding balun is optimized through impedance matching, which can avoid the problem of deterioration of the impedance characteristic caused by the reduction of the cross section of the radiating element.

Description of drawings

1 is a schematic perspective view of a preferred low-profile radiation unit of the present invention;

Figure 2 is a schematic plan view of the preferred low profile radiation unit of the present invention;

3 is a schematic plan view of the radiator of the preferred low-profile radiation unit of the present invention;

4A is a schematic perspective view of a feed balun of a preferred low-profile radiating element of the present invention;

4B is a horizontal schematic view of the first circuit board of the preferred feeding balun of the present invention;

4C is a horizontal schematic view of the second circuit board of the preferred feeding balun of the present invention;

5 is a schematic perspective view of the preferred small base station antenna of the present invention;

FIG. 6 is a horizontal schematic diagram of the preferred small base station antenna of the present invention.

detailed description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are only used to explain the present invention, but not to limit the present invention.

It should be noted that references in this specification to "one embodiment", "an embodiment", "example embodiment", etc., mean that the described embodiment may include specific features, structures or characteristics, but not every Embodiments must contain these specific features, structures or characteristics. Furthermore, such expressions are not referring to the same embodiment. Further, when a particular feature, structure or characteristic is described in conjunction with an embodiment, whether or not explicitly described, it has been shown that it is within the knowledge of those skilled in the art to incorporate such feature, structure or characteristic into other embodiments .

In addition, certain terms are used in the description and the following claims to refer to specific components or components, and it should be understood by those of ordinary skill in the art that manufacturers may use different terms or terms to refer to the same component or component. This specification and the following claims do not use the difference in name as a way of distinguishing components or parts, but use the difference in function of the components or parts as a criterion for distinguishing. References to "including" and "comprising" throughout the specification and subsequent claims are open-ended terms and should be interpreted as "including but not limited to". Otherwise, the term "connected" herein includes any direct and indirect means of electrical connection. Indirect electrical connection means include connection through other means.

1 to 4 show a preferred structure of the low-profile radiation unit 100 of the present invention, the low-profile radiation unit 100 at least includes a dielectric substrate 10 , a radiator 20 on the dielectric substrate 10 , and a feeding balun 30 . The radiator 20 includes two orthogonally distributed dipoles, which are respectively distributed in the ±45° direction of the dielectric substrate 10 to form two polarizations of ±45°, forming a dual-polarized radiation unit. The feeding balun 30 is in an orthogonal structure, the bottom of the feeding balun 30 is connected to the feeding network, the top of the feeding balun 30 is connected to the radiator 20, and each dipole is connected to each dipole through a feeding probe through coupling. sub-feed.

The existing radiating unit needs to place a metal reflector at a distance of 0.25λ from the radiator (or vibrator), and uses the feeding balun between the radiator and the grounding plate to feed, and the height of 0.25λ limits the size of the antenna. The invention provides a wide-band low-profile dual-polarized radiation unit, which adopts a coupling feeding method to feed and a deformed feeding balun to reduce the cross-sectional height of the radiation unit, thereby effectively realizing the goal of antenna miniaturization.

Due to the need for balanced feeding, the reduction of the height of the radiating surface of the existing radiating element will bring about the deterioration of the impedance characteristic. Preferably, the feeding balun 30 optimizes the impedance characteristic through impedance matching, so as to avoid the problem of deterioration of the impedance characteristic.

Preferably, the length of the feeding balun 30 is about 0.125λ, where λ is the wavelength of the working frequency band of the low-profile radiation unit 100 . The length of the existing feeding balun is about 0.25λ, and the reduction of the length of the feeding balun can reduce the profile of the radiating element.

3 shows the structure of the radiator of the preferred low-profile radiation unit of the present invention. The radiator 20 adopts a plane center-symmetric structure and consists of four radiating arms 21. The radiating arms 21 are leaf-shaped, that is, each leaf-shaped radiating arm 21 form a dual-polarized radiation unit, which is in the form of a four-leaf clover as a whole. The leaf-shaped circuit can make the radiation unit meet the electrical size required for excitation under a small diameter. The current path of each radiating arm 21 is about 0.25λ, and the current path of the radiating arm flows to the outer edge of the aperture, which can obtain a higher superposition gain of the radiation field. In the case of the same gain, the size of the aperture is reduced, which can effectively realize the multi-column low frequency The width dimension of the antenna array. Preferably, the side length of the aperture of the radiation surface of the radiator 20 is about 0.3-0.35λ, where λ is the wavelength of the operating frequency band of the low-profile radiation unit 100 .

As shown in FIG. 1 , the low-profile radiation unit 100 further includes a grounding sheet 40 . 4A to 4C show the structure of the feeding balun of the preferred low-profile radiating element of the present invention, the feeding balun 30 is composed of two orthogonally combined circuit boards 310 and 320, the circuit boards 310 and 320 are respectively It includes a dielectric sheet 31 , the front surface of the dielectric sheet 31 is distributed with bent and deformed feed lines 32 , and the back surface of the dielectric sheet 31 is covered with a ground 33 . Preferably, the feeding line 32 is a microstrip line, and the length of the feeding balun 30 is about 0.125λ. The bottom of the feed line 32 is connected to the feed network, the bottom of the ground 33 of the feed line 32 is connected to the ground plate 40 , and the top of the ground 33 is connected to the feed of the radiator 20 . Each dipole of the radiator 20 has a feeding balun 30, and the top of the feeding balun 30 feeds each dipole by coupling through a feeding probe.

Preferably, the circuit board includes a first circuit board 310 and a second circuit board 320, preferably a PCB circuit board. The first circuit board 310 is provided with a first fitting groove 311 , and the second circuit board 320 is provided with a second fitting groove 321 . The first circuit board 310 and the second circuit board 320 are respectively fitted with each other through the first fitting groove 311 and the second fitting groove 321 to form an orthogonal structure. The first circuit board 310 and the second circuit board 320 respectively correspond to one dipole.

As shown in FIG. 4B , the top of the first circuit board 310 is provided with at least two first upper tabs 312 , and the top of the second circuit board 320 is provided with at least two second upper tabs 322 . At least four upper slots 22 are correspondingly provided, and the first circuit board 310 and the second circuit board 320 are respectively clamped to the upper slots 22 of the radiator 20 through the first upper protrusions 312 and the second upper protrusions 322, Thereby a feed connection is achieved.

As shown in FIG. 4C , the bottom of the first circuit board 310 is provided with at least two first lower tabs 313 . The bottom of the second circuit board 320 is provided with at least two second lower protrusions 323, the grounding sheet 40 is provided with at least four lower slots 41 correspondingly, and the first circuit board 310 and the second circuit board 320 respectively pass through the first lower protrusions The sheet 313 and the second lower protruding sheet 323 are clamped at the lower slot 41 of the grounding sheet 40, so as to realize the connection between grounding and feeding.

5 to 6 show the preferred structure of the small base station antenna of the present invention. The small base station antenna 200 includes a reflector 300 on which a plurality of the low-profile radiating elements 100 are distributed. Preferably, a plurality of low-profile radiation units 100 form at least one line array and are distributed on the reflector 300 , each linear array includes at least three of the low-profile radiation units 100 , and adjacent low-profile radiation units 100 are arranged between adjacent low-profile radiation units 100 . The spacing is about 0.8˜1λ, where λ is the wavelength of the working frequency band of the low-profile radiation unit 100 .

To sum up, the low-profile radiation unit of the present invention includes a dielectric substrate, a radiator and a feeding balun. The radiator includes two orthogonally distributed dipoles, which are distributed and placed in the direction of ±45° of the dielectric substrate respectively. Dual polarized radiating element. The feeding balun is in an orthogonal structure, and the top of the feeding balun is connected to the radiator, and each dipole is fed by coupling through the feeding probe. In this way, the present invention adopts the method of coupling feeding and the form of deforming feeding balun to reduce the profile of the radiation unit, which can realize the broadband and low profile design of the radiation unit while ensuring the performance of the antenna, so as to achieve the purpose of miniaturizing the size of the antenna. . Preferably, the radiator is composed of four leaf-shaped radiation arms, and the leaf-shaped circuit can make the radiation unit meet the electrical size required for excitation under a small diameter, and can further reduce the cross-section of the radiation unit. More preferably, the impedance characteristic of the feeding balun is optimized through impedance matching, which can avoid the problem of deterioration of the impedance characteristic caused by the reduction of the cross section of the radiating element.

Of course, the present invention can also have other various embodiments, without departing from the spirit and essence of the present invention, those skilled in the art can make various corresponding changes and modifications according to the present invention, but these corresponding Changes and deformations should belong to the protection scope of the appended claims of the present invention.

Claims (10)

1. A low-profile radiation unit is characterized in that it includes a dielectric substrate, a radiator and a feeding balun; the radiator includes two orthogonally distributed dipoles, which are respectively in the ±45° direction of the dielectric substrate Distributed placement; the feeding balun is in an orthogonal structure, the bottom of the feeding balun is connected to the feeding network, the top of the feeding balun is connected to the radiator, and the feeding probe is coupled through a coupling method Feed each of the dipoles.
2. The low-profile radiating unit of claim 1, wherein the radiator is composed of four radiating arms, and the radiating arms are leaf-shaped.
3. The low-profile radiation unit according to claim 2, wherein the radiating surface of the radiator has an aperture side length of 0.3-0.35λ; and/or

   The current path of the radiation arm is 0.25λ;

   The λ is the wavelength of the working frequency band of the low-profile radiation unit.
4. The low-profile radiating element of claim 1, wherein the feed balun optimizes impedance characteristics through impedance matching.
5. The low-profile radiation unit according to claim 1, further comprising a grounding plate;

   The feeding balun is composed of two orthogonally combined circuit boards, each of the circuit boards includes a dielectric sheet, and the front surface of the dielectric sheet is distributed with feeding lines that are bent and deformed. The back is covered with ground; the bottom of the feed line is connected to the feed network, the bottom of the ground of the feed line is connected to the ground plate, and the top of the ground is connected to the radiator power feed.
6. The low-profile radiation unit according to claim 5, wherein the length of the feed balun is 0.125λ; and the λ is the wavelength of the working frequency band of the low-profile radiation unit.
7. The low-profile radiation unit according to claim 5, wherein the circuit board comprises a first circuit board and a second circuit board, the first circuit board is provided with a first fitting groove, and the second circuit board is provided with a first fitting groove. The circuit board is provided with a second fitting groove; the first circuit board and the second circuit board are respectively fitted into an orthogonal structure through the first fitting groove and the second fitting groove.
8. The low-profile radiation unit according to claim 7, wherein at least two first upper tabs are provided on the top of the first circuit board, and at least two second upper tabs are provided on the top of the second circuit board an upper tab, the radiator is correspondingly provided with at least four upper slots, and the first circuit board and the second circuit board pass through the first upper tab and the second upper tab respectively connected to the upper slot of the radiator;

   The bottom of the first circuit board is provided with at least two first lower tabs; the bottom of the second circuit board is provided with at least two second lower tabs, and the grounding sheet is correspondingly provided with at least four lower openings The first circuit board and the second circuit board are respectively clamped to the lower slot of the grounding sheet through the first lower tab and the second lower tab.
9. A small base station antenna is characterized in that it includes a reflector, and a plurality of low-profile radiation units according to any one of claims 1 to 8 are distributed on the reflector.
10. The small base station antenna according to claim 9, characterized in that, a plurality of the low-profile radiating elements form at least one line array and are distributed on the reflector, and the spacing between the adjacent low-profile radiating elements is 0.8˜1λ, where λ is the wavelength of the working frequency band of the low-profile radiation unit.

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