The present application claims priority under 35 U.S.C. § 119 to Chinese Patent Application No. 201810905275.8 (Serial No. 2018081001219430), filed Aug. 10, 2018, the entire content of which is incorporated herein by reference.
The present invention relates to the field of communications, and more particularly to a phase shifter assembly.
There are a large number of base stations in a mobile communication system. Each base station includes one or more base station antennas. The base station antennas are typically implemented as linear or planar arrays of radiating elements, where each radiating element will be referred to as an “antenna unit” herein. With a need to cover or optimize the mobile communication network, the elevation angle of an antenna beam generated by a base station antenna should have an adjustable orientation. This may be achieved, for example, by including a phase shifter in the base station antenna which can be used to adjust the phases of the sub-components of the radio frequency (RF) signals that are transmitted or received through the array of antenna units. By changing the phase distribution of the sub-components of the RF signals that are transmitted (or received) through each antenna unit of the array antenna, the downtilt angle of the antenna beam may be adjusted.
In practice, the phase shifters are mainly divided into two types, which are referred to herein as “medium” phase shifters and as “physical” phase shifters. Medium phase shifters implement the phase shift by changing the distance along a transmission line that corresponds to a wavelength of the RF signal by changing an electrical property of the transmission line. Physical phase shifters implement the phase shift by changing a physical length of the transmission line that the RF signal traverses.
Phase shifter assemblies are known in the art in which two physical phase shifters are provided in one plane side by side with each other. Each phase shifter is implemented as a so-called “wiper arm” phase shifter that includes a main printed circuit board and a rotatable wiper printed circuit board that is mounted above or below the main printed circuit board. The wiper printed circuit boards may be mounted on respective wiper supports, and each wiper support may be pivotally mounted for rotational movement with respect to a respective main printed circuit board. Each wiper support may include a pin that is received within a respective slot of a guide member. A pull rod of a mechanical linkage may drive the guide member, and movement of the guide member in turn acts to rotate the wiper supports in order to implement the phase shift. This phase shifter assembly, however, tends to occupy a large area within the base station antenna, so that it is possible to only arrange a limited number of these phase shifter assemblies within a predetermined area. In addition, the movement stroke of the pull rod of the mechanical linkage has a non-linear relationship with the rotation angle of the wiper supports, and the transmission accuracy is low, so that the adjustment of the phase shift is correspondingly low in accuracy.
From U.S. Patent Publication No. 2008/0024385A1 and U.S. Pat. No. 8,674,787B2 respectively, there is known a phase shifter assembly, wherein two phase shifters and other fittings are held together using a large number of fasteners. This phase shifter assembly includes a large number of parts, is expensive to assemble, and has limited accuracy in adjusting the phase shift.
A phase shifter assembly is provided that includes a first phase shifter and a second phase shifter. Each phase shifter may include a wiper printed circuit board that is, preferably fixedly, mounted on a rotatable wiper support. The phase shifter assembly further comprises a U-shaped bracket having a first arm, a second arm and a bottom edge connecting the first arm and the second arm, wherein the first phase shifter is mounted on the first arm, and the second phase shifter is mounted on the second arm; and a rack that is configured to move linearly.
At least one of the wiper supports is rotationally coupled to a tooth portion that engages the rack. The wiper supports are configured to rotate in response to linear movement of the rack, and wiper printed circuit boards are configured to rotate in response to rotation of the respective wiper supports within a predetermined range so as to implement respective phase shifts.
For example, a first of the wiper supports is rotationally coupled to a first tooth portion that is engaged with the rack. The second of the wiper supports may be configured to track the rotational movement of the first of the wiper supports or may be rotationally coupled to the first tooth portion or to a second tooth portion which is engaged with the rack. In response to linear movement of the rack, the wiper supports can be rotated respectively, and thus the wiper printed circuit boards are movable respectively within a predetermined range so as to implement a phase shift.
Here, by arranging the two phase shifters in two planes one above another, compared with the arrangement of the two phase shifters in the same plane, the area occupied by the phase shifter assembly may be reduced, that is, a larger number of phase shifter assemblies may be arranged in the same area. In addition, the rack transmission may have improved accuracy compared to the guide element transmission mechanism in the prior art.
In some embodiments, each wiper printed circuit board and a respective one of the wiper supports are constructed to be an integrated member; or each wiper printed circuit board and the respective one of the wiper supports are separate parts with each wiper printed circuit board mounted on the respective wiper support; or each wiper printed circuit board and the respective one of the wiper supports are separate parts and each wiper printed circuit board is coupled in motion with the respective wiper support by a transmission mechanism.
Thus, each pair of a wiper printed circuit board and a wiper support may be formed as a single integrated member. Alternatively, the wiper printed circuit boards and the respective wiper supports may be constructed as separated parts, and each wiper printed circuit board may be fixedly mounted on a respective one of the wiper supports. As a further alternative, each wiper printed circuit board and its associated wiper support may be constructed as separate parts, and the wiper printed circuit board may be coupled in motion with the wiper support by a transmission mechanism. For example, it is possible that the rotational movement of the wiper support is converted into a linear movement of the wiper printed circuit board by means of the transmission mechanism. It is particularly advantageous that, the wiper printed circuit board and the wiper support are fixed to each other and thus can be moved together.
The rotational coupling of each of the wiper supports to a tooth portion may for example be implemented as follows: the rotational movement of the tooth portion is converted into a rotational movement of the wiper support by means of a reduction transmission mechanism. It may be particularly advantageous that the single wiper support and the corresponding tooth portion be connected rotation-fixedly, and especially constructed integrally, thus minimizing the number of parts.
In some embodiments, each wiper support has a first end and a second end, where each wiper support is rotatably supported on the bracket or on the respective phase shifter at its first end, and has the tooth portion on its second end that is integrated or connected rotation-fixedly.
In some embodiments, the first and second phase shifters are arranged to overlap with each other. Accordingly, it is possible to minimize the area occupied by the phase shifter assembly, so that it is only necessary to occupy about half of the area compared to the prior art. It is also possible that, the two phase shifters are arranged to be staggered parallel to each other.
In some embodiments, the first and second phase shifters respectively include a main printed circuit board, and the wiper printed circuit board is slidable on a predetermined area of the main printed circuit board to implement the phase shift. For example, the main printed circuit board may be provided with a phase shift circuit, and the wiper printed circuit board moves relative to the main printed circuit board, so that there is a change in the length of the transmission path of the RF signal, thereby implementing the phase shift.
In some embodiments, conductor guiding portions are provided on the U-shaped bracket in such a way as to be adjacent the respective longitudinal ends of each of main printed circuit boards, wherein respective first ends of a plurality of conductors are connected to the main printed circuit boards by passing through the respective conductor guiding portions. This connection may be achieved, for example, by soldering.
In some embodiments, the U-shaped bracket is constructed as an integral component. Alternatively, the bracket may also be formed by connecting a plurality of members.
In some embodiments, the U-shaped bracket is a metal cast member or a metal sheet formed member or a plastic molded member. The assembly of other parts of the phase shifter assembly is facilitated by the U-shaped bracket.
In some embodiments, from one of the arms of the U-shaped bracket, at least one support leg projects at an angle with the one arm. Thereby, the phase shifter assembly can be easily installed in a housing. The support leg may be an integral constituent part of the U-shaped bracket, for example fabricated together during the casting or during the punch forming; and may also be a separate member and connected to the bracket, for example connected by screws, riveted or welded.
According to further embodiments, the phase shifter assembly may further comprise a shielding member that extends around the first and second phase shifters.
Pursuant to further embodiments of the present invention, a phase shifter assembly is provided that comprises a bracket having a first arm, a second arm that is spaced apart from the first arm by a gap and a bottom edge connecting the first arm and the second arm, a first phase shifter that includes a first main printed circuit board and a first wiper printed circuit board that is mounted for rotation with respect to the first main printed circuit board, the first phase shifter mounted on the first arm of the bracket, a second phase shifter that includes a second main printed circuit board and a second wiper printed circuit board that is mounted for rotation with respect to the second main printed circuit board, the second phase shifter mounted on the second arm of the bracket, and a rack that is configured to move linearly. The rack includes at least one first toothed portion and at least one of the first and second phase shifters includes a second toothed portion that engages the first toothed portion, so that the first and second wiper printed circuit boards are configured to rotate in response to linear motion of the rack in order to implement respective phase shifts.
In some embodiments, the first phase shifter further comprises a first clip that biases the first wiper printed circuit board against the first main printed circuit board, wherein a first portion of the first clip is on a first side of the first arm and a second portion of the first clip is on a second side of the first arm that is opposite the first side.
In some embodiments, the first arm is parallel to the second arm.
In some embodiments, the first phase shifter is mounted on an upper surface of the first arm and the second phase shifter is mounted on a lower surface of the second arm.
In some embodiments, the first phase shifter further comprises a first wiper support that has a first end and a second end, wherein the first end of the first wiper support is pivotally mounted above the first main printed circuit board and the second toothed portion is part of the second end of the first wiper support.
In some embodiments, the bracket is a monolithic bracket.
In some embodiments, the bracket includes a first support leg that projects at an angle from a side of the second arm.
In some embodiments, the support leg includes a lip that projects at an angle from a distal end of the support leg.
In some embodiments, the bracket comprises a U-shaped bracket.
The phase shifter assembly according to the embodiments of
The first phase shifter 11 is disposed on the first arm 3 of the bracket 1, and the second phase shifter 12 is disposed on the second arm 4 of the bracket 1. The first and second phase shifters are arranged to overlap with each other. The first and second phase shifters respectively include a main printed circuit board fastened to the bracket 1 by screws, wiper supports 15, 16 rotatably supported on the respective main printed circuit boards, and wiper printed circuit boards 13, 14 that are fixedly mounted on the respective wiper supports 15, 16. The wiper supports 15, 16 respectively include tooth portions 17, 18. The wiper printed circuit boards 13, 14 abut against predetermined areas of the respective main printed circuit boards.
The rack 2 of the phase shifter assembly may also be seen in
When the rack 2 is driven, for example, by a stepper motor, the rack 2 moves linearly, and the wiper supports 15, 16 are driven to rotate, so that the wiper printed circuit boards 13, 14 rotate with respect to the respective main printed circuit boards, thereby implementing the phase shifts.
In the embodiments shown in
In the embodiments shown, the two wiper supports 15, 16 are each provided with an integral tooth portion, and thus each wiper support 15, 16 and the respective tooth portion are rotation-fixed. It is also possible that each tooth portion is constructed as a separate member that is connected to the respective wiper support 15, 16 so that rotation of a tooth portion results in a corresponding rotation of the respective wiper support 15, 16.
The bracket 1 includes a plurality of sets of conductor guiding portions 19. For example, a set of conductor guiding portions 19 may be provided at each side of each of the main printed circuit boards (for a total of four sets of conductor guiding portions 19). Each conductor guiding portion 19 may be implemented, for example, as a clip or other structure that receives a respective conductor. A plurality of conductors (not shown) such as, for example, coaxial cables, may be soldered to each main printed circuit board, and each conductor guiding portion 19 may receive a respective one of these coaxial cables. A support leg 20 projects substantially in a perpendicular manner, respectively at both ends of the second arm 4 of the bracket 1 in a longitudinal direction. Each support leg 20 includes a lip 22 that is provided with screw holes, for fastening the bracket 1 to the housing (not shown) by screws.
As can best be seen in
If two wiper arm printed circuit boards are mounted on opposite sides of a support plate, it may be difficult to use the above-described support clips. For example, if a support clip is added to the phase shifter mounted on an upper surface of the support plate, the bottom portion of the clip will need to extend below the support plate. However, in this position, the support clip may interfere with operation of the phase shifter that is mounted on the lower surface of the support plate.
By providing the U-shaped bracket 1 having first and second arms 3, 4 that are separated by a gap 25, it is possible to mount the phase shifters on two different arms, each of which serves as a respective support plate. Accordingly, a clip may be used with each phase shifter to bias the wiper printed circuit board to press against the main printed circuit board, since the clip for a first phase shifter will not get in the way of operation of the second phase shifter. The gap 25 also spaces the sets of conductor guiding portions 19 for the first phase shifter from the sets of conductor guiding portions 19 for the second phase shifter.
As can best be seen in
Finally, it is to be noted that, the above-described embodiments are merely for understanding the present invention but do not constitute a limit on the protection scope of the present invention. For those skilled in the art, changes may be made on the basis of the above-described embodiments, and these changes do not depart from the protection scope of the present invention. The technical features recited in the present application can be arbitrarily combined as long as such combinations are not contradictory to each other, and all of these combinations are the technical contents recited in the present application.
Number | Date | Country | Kind |
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2018 1 0905275 | Aug 2018 | CN | national |
Number | Name | Date | Kind |
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8674787 | Bradley et al. | Mar 2014 | B2 |
20060077098 | Zimmerman | Apr 2006 | A1 |
20080024385 | Zimmerman | Jan 2008 | A1 |
20100053008 | Le | Mar 2010 | A1 |
20110063049 | Bradley | Mar 2011 | A1 |
20160134007 | Ding | May 2016 | A1 |
20200006848 | Ding | Jan 2020 | A1 |
Number | Date | Country |
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207303304 | May 2018 | CN |
Number | Date | Country | |
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20200052397 A1 | Feb 2020 | US |