EP2253046B1

EP2253046B1 - Multi-beam antenna with multi-device control unit

Info

Publication number: EP2253046B1
Application number: EP09711078.7A
Authority: EP
Inventors: Grégory GIRARD; Frank Soulie; Eric Proteau; Anthony Pallone
Original assignee: Amphenol Corp
Current assignee: Amphenol Corp
Priority date: 2008-02-11
Filing date: 2009-02-11
Publication date: 2020-10-28
Anticipated expiration: 2029-02-11
Also published as: EP2253046A2; CN102150374B; KR101589580B1; CN102150374A; WO2009102775A3; MX2010008827A; WO2009102774A2; IL207479A; WO2009102775A2; CA2725888A1; CN102150325B; IL207480A0; KR20100122092A; IL207479A0; MX2010008830A; CA2725886C; WO2009102774A3; CA2725886A1; IL207480A; CA2725888C

Description

REFERENCE TO PRIORITY APPLICATIONS

This application claims priority to commonly-owned United States Provisional Patent Application No. 60/027,687 .

TECHNICAL FIELD

This invention relates to the field of cellular or mobile telephone base station antennas and, more particularly, relates to a remote electrical tilt (RET) base station antenna with a removable multi-device control unit that can be switched to remotely control more than one electro-mechanical actuator contained inside the antenna.

BACKGROUND OF THE INVENTION

Antennas with variable electrical tilt (VET) functionality are known in the art. These antennas, which are used in cellular networks, enable network operators to electrically tilt the elevation beam pointing direction of the antenna by manually rotating a knob or translating a shaft on the exterior of the antenna. The knob or shaft is linked to phase shifters inside the antenna that convert the mechanical rotation or translation of the shaft to phase changes in the radio frequency beam forming network inside the antenna. Changes in phase between radiating elements inside the antenna cause the beam emitted from the antenna to tilt up or down relative to mechanical boresite of the antenna. An example of a cellular base station antenna demonstrating VET technology is depicted in US 7,068,236 .
Beam tilt adjustment is needed in cellular networks to reduce signal propagation between sites in the network in order to minimize signal interference and to maximize network capacity. Antennas with VET functionality allow network operators to make accurate tilt adjustments at a cell site without mechanically tilting the antenna and without changing the visual appearance of the site. Antennas with VET functionality typically include some sort of tilt indicator to provide visual feedback of the antenna electrical tilt setting to a person located at the antenna to inspect the antenna or to manually make the tilt adjustment.
Remote electrical tilt (RET) antennas are also known in the art. RET antennas incorporate an electro-mechanical actuator attached to or installed inside of the antenna to rotate the knob or translate the shaft on a VET antenna. This enables the electrical tilt of the VET antenna to be controlled from a remote location, eliminating the expense of hiring a rigger to climb the tower and manually adjust the electrical tilt of the antenna beam.
This conventional configuration of RET actuators is shown in FIG 1, in which a tri-band antenna 4 includes three self contained, separately removable RET actuators 5a-c, one for each operational frequency band of the antenna. Each RET actuator is a self contained electro-mechanical device with lightning protection circuits, communications circuits, a motor, motor control circuits, power control circuits and a motor position sensor contained within a single enclosure. For antennas designed to operate over multiple frequency bands, multiple, stand-alone RET actuators are attached to or inserted inside of the antenna housing. Cable assemblies are connected between the RET actuators to provide power and signaling to the multiple RET actuators for that antenna. This design approach is expensive due to the cost of the external cable assemblies and the redundant electronic components used by multiple RET actuators. In addition, removable RET actuators must be configured to physically align with and receive the phase shifter shafts for each beam of the multi-beam antenna, which requires a different removable RET actuator configuration for each antenna with a different phase shifter shaft configuration.
The locations of the phase shifter adjustment knobs or shafts on a typical multi-band RET antenna are constrained by the physical size and shape of the RET actuators and by their attachment mechanisms. The phase shifter adjustment knobs or shafts must be spaced far enough apart to allow the multiple RET actuators to be attached to the antenna without mechanical interference. The knobs or shafts must also be spaced far enough apart to provide room for the RET actuator mounting hardware and to provide access for the tools used to install the mounting hardware. As a result, the location of the phase shifter adjustment knobs or shafts on the antenna are often determined by the geometry of the RET actuators and not by the optimum phase shifter placement inside the antenna. These constraints increase the mechanical complexity of the RET antenna design and increase the development time and costs for new antenna models.
There is, therefore, a continuing need for a RET antenna that can be produced with fewer electronic parts for lower cost and that reduces mechanical constraints on the phase shifter drive shaft locations inside the antenna.
US6239744 discloses the features of the pre-characterising portion of claim 1. Further, US 2007/0030208 discloses a controller that feeds a signal to a control interface which in turn sends the signal to an antenna interface which in turn sends commands, extracted from the received signal, to a control actuator which controls an antenna.

SUMMARY OF THE INVENTION

The present invention meets the need described above in a RET antenna with a multi-device control unit that is configured to be inserted into and removed from a receptacle in the antenna. The multi-device control unit works with one or more modular switching units, which are typically located inside the antenna enclosure, to control the motors and position sensors located inside the antenna to allow a single controller located in the multi-device control unit to control multiple embedded electro-mechanical actuators, such as phase shifter control motors. This enables multiple motors to share a common control system located in the multi-device control unit, which greatly reduces the number of electronic components required for a multi-beam RET antenna.
The multi-device control unit typically includes one or more lightning protection circuits, communications circuits, motor controllers, power control circuits and motor position sensing circuits inside a small housing, which is usually located inside the antenna housing at the time of manufacture. These components are shared between all motors inside the antenna through the modular switching unit, which allows a single set of components within the multi-device control unit to replace redundant components deployed in prior RET actuators. The modular switching unit monitors an internal addressing bus and closes the connections to the appropriate motor and motor position feedback sensor based on the hardware address for that motor. The modular switching unit is configured to be inserted into a receptacle in the antenna body and secured with two mounting screws
In one aspect, the invention provides a base station antenna according to independent claim 1.
The modular switching unit is typically located inside the enclosure and the multi-device control unit is typically configured for manual insertion into and removal from a receptacle supported by the housing, which is typically open to the exterior of the antenna. The multi-device control unit typically includes a lightning protection circuit, a communications interface, and an internal addressing interface, which are sufficient components for the multi-device control unit. The modular switching device typically includes at least one switch, a signal routing device, and a plurality of address registers with each register associated with a beam system of the antenna, which are sufficient components for the modular switching device.
In another aspect the invention provides a method for providing a base station antenna according to independent claim 7.
In view of the foregoing, it will be appreciated that the present invention provides a cost effective RET antenna that includes a multi-device control unit that greatly reducing the number of electronic components required for a multi-RET system. The specific techniques and structures for implementing particular embodiments of the invention, and thereby accomplishing the advantages described above, will become apparent from the following detailed description of the embodiments and the appended drawings and claims.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 is an electrical schematic of a prior art configuration for a tri-band antenna with three removable RET actuators.
FIG. 2 is an electrical schematic of a tri-band RET antenna with a multi-device control unit and internal switching devices.
FIG. 3 is a perspective view of a tri-band RET antenna with a multi-device control unit.
FIG. 4 is a front view of the RET control equipment in an RET antenna with a multi-device control unit.
FIG. 5 is a bottom view of the antenna enclosure of an RET antenna with a multi-device control unit.
FIG. 6 is a front perspective view of a multi-device control unit and associated receptacle.
FIG. 7 is a rear perspective view of the multi-device control unit and associated receptacle.

DETAILED DESCRIPTION OF THE EMBODIMENTS

The present invention meets the need described above in a RET antenna with a multi-device control unit that can be inserted into and removed from a receptacle in the antenna. The multi-device control unit works with one or more modular switching units, which are typically located inside the antenna enclosure. The multi-device control unit works together with motors and position sensors located inside the antenna to allow a single controller located in the multi-device control unit to control multiple embedded electro-mechanical actuators, such as phase shifter control motors. This enables multiple motors to share a common control system located in the multi-device control unit, which greatly reduces the number of electronic components required for a multi-beam RET antenna.
The multi-device control unit typically includes one or more lightning protection circuits, communications circuits, motor controllers, power control circuits and motor position sensing circuits inside a small housing that is usually located inside the antenna enclosure. These components are shared between multiple motors inside the antenna through the modular switching unit, which allows a single set of components within the multi-device control unit to replace redundant components deployed in prior RET actuators. The modular switching unit monitors an internal addressing bus and closes the connections to the appropriate motor and motor position feedback sensor based on the hardware address for that motor. This enables multiple motors to share a common control system, greatly reducing the number of electronic components required for a multi-RET system.
An electronic connector on the multi-device control unit plugs into a mating connector on a receptacle mounted to the antenna enclosure to provide power, signaling and motor position feedback between the multi-device control unit and the motors and position sensors inside the antenna. The motors and motor position feedback sensors associated with each phase shifter adjustment shaft are permanently attached inside the antenna. This configuration eliminates the mechanical drive train and linkage interface of conventional RET actuators and replaces it with an electrical interface, implemented by the multi-device control unit, between the RET controller and the antenna. The electrical connections inside the antenna are made with a wiring harness which is flexible and does not constrain the mounting location for the motors and motor position sensors inside the antenna.
An additional benefit of this design is that a customer does not need to perform a calibration step at installation. The position feedback sensors are installed and calibrated at the factory. Since there is never a mechanical separation in the phase shifter drive chain after the antenna leaves the factory, calibration is never lost. The present invention can be used for control of electro-mechanical actuators inside the antenna for purposes other than remote electrical beam tilt (RET.) Actuators for remote azimuth beam steering (RAS) and/or remote azimuth beam width control (RAB) can also be controlled using the same multi-device control unit.
Turning now to the figures, in which like element numerals refer to similar element throughout the figures, FIG. 1 is an electrical schematic of a prior art configuration for a tri-band antenna 4 with three removable RET actuators 5a-c. In this arrangement, there is a mechanical interface 7 forming a drive train linkage between the antenna 4 and the RET actuators 5a-c. The tri-band antenna 4 includes three self contained, separately removable RET actuators 5a-c, one for each antenna array implementing an operational frequency band of the antenna. Referring to the RET actuator 5a as a representative unit, the RET actuator is a self contained electro-mechanical device with lightning protection circuits 52a and 54a, a communications interface 56a, a position sensor interface 58a, a motor control interface 60a, a power control circuit 62a, a motor 64a, and a position sensor 66a contained within a single enclosure 67a. A drive rod 68a extending through the enclosure drives the phase shifters of an associated antenna array 70a. Therefore, the RET actuators 5a-c contain a complete duplication of the equipment needed to control the electrical tilt of an array transmitting and receiving the signals for one beam of a multi-beam antenna. In addition, the drive rods 68a-c must mechanically interface with the control rods of the antenna arrays 70a-c, resulting in a physically restrictive and potentially complicated mechanical interface 7.
FIG. 2 is an electrical schematic of an antenna system 10 including a dual-polarization, tri-band RET antenna 12 and a multi-device control unit 20. The multi-device control unit 20 includes lightning protection circuits 72 and 74, a communications interface 76, an internal addressing interface 82, a motor control interface 84, a position sensing interface 86, and a power control circuit 88. The multi-device control unit 20 works together with modular switching devices 14a-b, which are typically located inside the antenna enclosure, to control the phase shifters to implement electrical beam tilt for up to four bands of a multi-band antenna. The multi-device control unit 20 and the modular switching devices 14a-b shown in FIG. 2 therefore replace up to four sets of components (i.e., those components in the multi-device control unit) in the prior art design shown in FIG. 1 . The single set of components in the multi-device control unit 20 works in concert with the modular switching devices 14a-b to control the electrical tilt for all three beams of the antenna with the single set of control components in the multi-device control unit 20 with one of the four potential control circuits dormant in this particular configuration. It should be appreciated that the multi-device control unit 20 may be may be configured to control additional dev ices. For example, a typical control unit can support up to 16 motor/position sensors. Although FIG. 2 shows only two modular switching devices 14a-b eight modular switching devices are typically installed, and a larger or smaller number could be installed as a matter of design choice.
As each modular switching device 14a-b is identical, a representative modular switching device 14a will be described. The modular switching device, which is configured to relay tilt control commands from the multi-device control unit 20 for up to two operational bands implemented by antenna arrays, drives up to two existing internal phase shifter motors 90a-b and interfaces with up to two existing internal position sensors 92a-b of the host antenna. The modular switching device 14a itself includes switches 94a-b, fixed address registers 96a-b, and a comparator 98a. The comparator, which operates as a signal routing device to route control commands to the appropriate switch, could be replaced by functionality in or associated with the address registers or any other suitable signal routing device that directs addressed signals to an associated addressed device. However, it will be appreciated that with only two addresses to route, a simple comparator is adequate for the signal routing task in this particular embodiment. Control logic in the multi-device control unit 20 operates cooperatively with the fixed address registers 96a-b and the comparator 98a to selectively control the phase shifter motors 90a-b. As result, the multi-device control unit 20 can independently control up to four phase shifter motors through the pair of modular switching devices 14a-b. Of course, a greater or smaller number of phase shifter motors could be controlled at the particular antenna requires.
It should be appreciated that the RET motors and position sensors are the motors and position sensors originally provisioned in the antenna 12, which avoids the need for a mechanical linkage between the multi-device control unit 20 and the antenna 12. Therefore, there is only an electrical interface 15 is required between the multi-device control unit 20 and the antenna 12, as shown schematically in FIG. 2. If desired, the motors 90a-b, position sensors 92a-b, and switching devices 14a-b can be installed but remain dormant in the antenna 12 in the absence of the multi-device control unit 20. This allows the antenna 12 to be provisioned at the factory to be easily converted from manual tilt control to RET motorized tilt control through the addition of the multi-device control unit 20. Although the motors 90a-b, position sensors 92a-b and switching devices 14a-b are provisioned but left dormant in a manual tilt control antenna in this alternative, the cost of providing these components is more than offset by the benefit of eliminating the mechanical linkage and accompanying physical design constraints required to connect the prior art style RET actuator to the antenna.
The modular switching devices 14a-b and associates wiring are preferably located in strategic locations inside the antenna enclosure at the time of manufacture. Nevertheless, as an alternative arrangement, the multi-device control unit 20 may be installed at the factory as original equipment, and a module containing the switching devices 14a-b may fit into the receptacle. In this case, the switching module is provided to the customer upon request for the optional RET functionality. As another alternative, the multi-device control unit 20 and the modular switching devices 14a-b may be combined into an integrated control module that fits into the receptacle. In this case, the integrated control module is provided to the customer upon request for the optional RET functionality. As yet another alternative, the combined functionality of the multi-device control unit 20 and the modular switching devices 14a-b may be installed inside or in association with the antenna at the factory as original equipment, and an activation device or activation code may be provided to the customer upon request for the optional RET functionality.
The advantages of the present invention can be enhanced with additional motorized actuators, for example for beam azimuth steering and beam width control. In particular, the same size multi-device control unit 20 with additional switching devices located in strategic locations inside the antenna can control many motorized actuators to perform these and other antenna functions. Therefore, the multi-device control unit scheme can be extended to a wide range of motorized actuators performing a wide range of functions within the antenna without the physical limitations of mechanical linkages between the antenna and removable remote control actuators.
FIG. 3 is a perspective view of the bottom portion of the antenna system 10 including the tri-band antenna 12 shown substantially to scale. For this particular antenna, the maximum width across the bottom of the antenna enclosure 25 is approximately 10 inches (24.5 cm) and the maximum depth across the bottom of the antenna enclosure is approximately 6 inches (14.2 cm). The height of the antenna is not shown and can vary considerably for different embodiments. For example, a typical tri-band antenna 12 may be approximately 8 feet 10 inches (2.7 meters) tall. The bottom of the enclosure 25 carries six cable connectors represented by the enumerated cable connector 16. Each vertical array transmits and receives one band of the tri-band antenna, and each band has two cable connectors, one for each polarization. Also at the bottom of the enclosure, there are three manual beam tilt adjusters (including a beam tilt indicator displayed on the bottom portion of a phase shifter control rod, a manual beam tilt adjustment knob connected to the bottom of the phase shifter control rod, and an indicator cover) represented by the enumerated manual beam tilt adjuster 32 with a manual adjustment knob 18 the end. The antenna system 10 also includes the multi-device control unit 20, which fits into a receptacle 22 (shown in FIGS. 4-7) in the antenna housing on the bottom of the enclosure 25.
FIG. 4 is a front view of the RET control equipment in the antenna 12. There are three phase shifter control rods represented by the phase shifter control rod 24, three gear-motor units represented by the gear-motor unit 26, and three position sensors represented by the enumerated position sensor 28. A receptacle 22 receives the multi-device control unit 20, physically supports and electrically connects to the switching devices 14a-b, which are implemented on PC cards. The switching devices 14a-b are electrically connected by wires 35a-b that go to the gear motors and positions sensors, as shown in FIG. 4 and schematically in FIG. 2.
FIG. 5 is a bottom view of the antenna enclosure 25 of an RET antenna 12. The enclosure 25 carries the receptacle 22 (shown without the multi-device control unit in FIG. 5) for receiving the multi-device control unit 20, which plugs into receptacle and is secured by two screws. FIG. 6 is a front perspective view and FIG. 7 is a rear perspective view of the multi-device control unit 20 and the associated receptacle 22. The front of the multi-device control unit 20 includes cable connectors 30 for connecting the multi-device control unit to a remote control unit. The rear of the multi-device control unit includes a plug 32, such as a PC board edge connector, that plugs into a connector 34 on the receptacle 22. The switching devices 14a-b plug onto the connector 34 and, in turn, are connected by wire to the gear-motors and position sensors located inside the antenna, as shown in FIG. 4.

Claims

A base station antenna (10) for a telecommunications system comprising:
a plurality of beam systems supported by an antenna housing, each beam system comprising a plurality of antenna elements for directing a beam of electromagnetic energy in a propagation direction, a plurality of phase shifters operatively connected to the antenna elements for tilting the beam propagation direction, a control device operatively connected to the phase shifters for operating the phase shifters to tilt the beam propagation direction, a gear-motor unit (90a, 90b, 90c, 90d), comprising a phase-shifter control motor, operatively connected to the control device for electro-mechanically driving the control device to tilt the beam propagation direction, and a position sensor (92a, 92b, 92c, 92d) for sensing the position of the phase shifter control motor;

the base station antenna further comprising:
a multi-device control unit (20) operative to selectively control the beam propagation direction of each beam system, the multi-device control unit comprising a position sensing interface (86), a motor control interface (84), a power control circuit (88), a communications interface (76) and an internal addressing interface (82); and

at least one modular switching device (14a, 14b) configured to interface between the multi-device control unit and the gear-motor units and position sensors of the beam systems to allow a single set of control electronics of the multi-device control unit to selectively control the beam propagation direction of each beam system, by selectively connecting the motor control interface and the power control circuit of the multi-device control unit to the gear-motor units of each beam system, and by selectively connecting the position sensing interface of the multi-device control unit to the position sensors of each beam system.
The antenna of claim 1, wherein the multi-device control unit (20) is configured for manual insertion into and removal from a receptacle (22) supported by the housing.
The antenna of claim 1, wherein the modular switching device is located inside an enclosure (25) of the antenna housing.
The antenna of claim 1, wherein the multi-device control unit further comprises a lightning protection circuit (72, 74).
The antenna of claim 1, wherein the modular switching device comprises at least one switch (94a, 94b, 94c, 94d), a signal routing device (98a, 98b), and a plurality of address registers (96a, 96b, 96c, 96d), each register associated with a beam system of the antenna.
The antenna of any preceding claim, further comprising:
a receptacle (22) supported by the housing, wherein

the multi-device control unit (20) is configured for manual insertion into and removal from the receptacle.
A method for providing a base station antenna (10) for a telecommunications system with optional multi-beam remote electronic tilt (RET) control functionality, comprising the steps of:
providing an antenna operator with an antenna (12) comprising a plurality of beam systems supported by an antenna housing, each beam system comprising a plurality of antenna elements for directing a beam of electromagnetic energy in a propagation direction, a plurality of phase shifters operatively connected to the antenna elements for tilting the beam propagation direction, a control device operatively connected to the phase shifters for operating the phase shifters to tilt the beam propagation direction, a gear-motor unit (90a, 90b, 90c, 90d), comprising a phase-shifter control motor, operatively connected to the control device for electro-mechanically driving the control device to tilt the beam propagation direction, and

a position sensor 92a, 92b, 92c, 92d) for sensing the position of the phase shifter control motor; the method further comprising the steps of:
provisioning the antenna prior to delivery to the antenna operator with a receptacle (22) supported by the housing;

provisioning the antenna prior to delivery to the antenna operator with a modular switching device (14a, 14b) operable to interface between a multi-device control unit, the multi-device control unit (20) comprising a position sensing interface (86), a motor control interface (84), a power control circuit (88), a communications interface (76) and an internal addressing interface (82), and the gear-motor units and position sensors of the beam systems to allow a single set of control electronics of the multi-device control unit to selectively control the beam propagation direction of each beam system, by selectively connecting the motor control interface and the power control circuit of the multi-device control unit to the gear-motor units of each beam system, and by selectively connecting the position sensing interface of the multi-device control unit to the position sensors of each beam system; and

in response to a request from the antenna operator for optional multi-beam RET control functionality received after initial delivery of the antenna, providing the antenna operator with the multi-device control unit.
The method of claim 7, wherein the multi-device control unit (20) further comprises a lightning protection circuit (72, 74).
The antenna of claim 8, wherein the modular switching device consists essentially of one or more switches (94a, 94b, 94c, 94d), a signal routing device (98a, 98b), and a plurality of address registers (96a, 96b, 96c, 96d), each register associated with a beam system of the antenna.