The present invention relates to the field of wireless communications, and more particularly, to a steerable antenna assembly for a satellite and related methods.
Steerable satellite antenna assemblies for satellite-to-ground links typically require high gain, low mass, and high reliability. One approach for a steerable satellite antenna assembly is to use a fixed feed source so as to eliminate performance degradations otherwise associated with a moving feed source. Performance degradations for a moving feed source typically include losses due to mechanical rotary joints, RF cable connectors, flexible waveguides, and lengthy cables associated with rotary actuators.
Steerable satellite antenna assemblies also need to avoid the “keyhole effect,” which is a physical limitation due to the orientation of the antenna rotation axis caused by a limited motion range of the actuators. The keyhole effect causes the antenna to momentarily disrupt communications when reaching its physical limitation so as to allow for the actuators to reposition before resuming steering.
One approach for a steerable satellite antenna assembly with a fixed antenna feed is disclosed in U.S. Pat. No. 6,492,955 to Amyotte et al. The antenna assembly includes a subreflector secured to a frame rotatably mounted on a support structure via a first motor, and an antenna feed located at a first focus of the subreflector for illuminating the same. The antenna feed is fixed to the structure and has a feed axis pointing at the subreflector. A parabolic reflector having a focus in common with a second focus of the subreflector to transfer the signal between the same, and a planar reflector is secured to the frame, and has a beam axis. The planar reflector is rotatably mounted on the frame via a second motor to transfer the signal between the parabolic reflector and a target. The antenna assembly includes a controller connected to the motors to steer at the target anywhere within a full spherical angular range.
Another approach for a steerable satellite antenna assembly with a fixed antenna feed is disclosed in U.S. Pat. No. 5,198,827 to Seaton. The antenna assembly includes an antenna feed structure for emitting electromagnetic radiation, and a subreflector for redirecting the emitted radiation. A main antenna reflector projects radiation redirected by the subreflector as an antenna beam. A mechanical arrangement rotates the subreflector about the rotation point.
Even in view of the above steerable satellite antenna assemblies, there is still a need for such assemblies to have a more compact geometry. Continued growth and demand for bandwidth has led to new commercial satellite constellations. For example, the O3b satellite constellation is deployed in a medium earth orbit (MEO) and the OneWeb satellite constellation is to be deployed in a low earth orbit (LEO). A more compact antenna assembly reduces the size and weight of the satellites, as well as costs. In addition, MEO and LEO satellites typically operate at a wider beam scanning range as compared to a traditional geosynchronous orbit. Consequently, another desirable attribute is for the compact antenna assemblies to also operate over a wider scanning range.
An antenna assembly to be carried by a satellite according to the invention comprises an antenna feed configured to extend outwardly from the satellite, a frame rotatably carried by the antenna feed and rotatable about a first rotation axis, and a main reflector carried by the frame and aligned with the antenna feed. A splash plate may be carried by the frame in spaced apart relation from the main reflector, and may be rotatable about a second rotation axis.
Since the antenna assembly does not require a subreflector, this allows for the antenna assembly to have a more compact geometry. A compact antenna assembly reduces the size and weight of the satellite. Satellite cost is also reduced since less parts are used.
The antenna feed and mounting interface may have an L-shape. The main reflector may be fixed to the frame. The main reflector may have a parabolic shape, and the splash plate may have a flat shape. The antenna feed and main reflector may be configured to operate in at least one of the Ka-frequency band and the Ku-frequency band.
The antenna assembly may further comprise a first rotational actuator coupled between the antenna feed and the frame, and a second rotational actuator coupled between the frame and the splash plate. The first rotation axis may provide azimuthal positioning, and the second rotation axis may provide elevational positioning.
Another aspect is directed to a satellite comprising a housing, communications circuitry carried by the housing, and an antenna assembly also carried by the housing. The antenna assembly may be as described above.
Yet another aspect is directed to a method for making an antenna assembly as described above. The method may comprise positioning an antenna feed to extend outwardly from the satellite, and positioning a frame to be rotatably carried by the antenna feed. The frame may be rotatable about a first rotation axis. A main reflector may be positioned to be carried by the frame and be aligned with the antenna feed. A splash plate may be positioned to be carried by the frame in spaced apart relation from the main reflector. The splash plate may be rotatable about a second rotation axis.
The present invention will now be described more fully hereinafter with reference to the accompanying drawings, in which preferred embodiments of the invention are shown. This invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete, and will fully convey the scope of the invention to those skilled in the art. Like numbers refer to like elements throughout.
Referring initially to
The fixed antenna feed 42 is configured to extend outwardly from the satellite housing 30, as illustrated in
The first rotation axis 70 provides azimuthal positioning, and the second rotation axis 72 provides elevational positioning. The antenna feed has an L-shape and the main reflector 44 is fixed to the frame 43. The main reflector 44 has a parabolic shape, and the splash plate 46 has a flat shape.
In a transmit mode, RF signals from the antenna feed 42 are directed to the main reflector 44. The main reflector 44 reflects the RF signals to the splash plate 46 which is then positioned to direct the RF signals to an intended transceiver. The intended transceiver may be on the ground or on an air-borne platform, for example. In a receive mode, the transmit path is reversed.
Since the antenna assembly 40 does not require a subreflector, this allows for the antenna assembly to have a more compact geometry. A compact antenna assembly reduces the size and weight of the satellite 20. Satellite cost is also reduced since less parts are used.
In the illustrated embodiment, the communications circuitry 50 and the antenna assembly 40 are configured to operate in the Ka-band, which corresponds to 17-29 GHz. Alternatively, the communications circuitry 50 and the antenna assembly 40 may be configured to operate in the Ku-band, which corresponds to 10-14.5 GHz. As readily appreciated by those skilled in the art, the communications circuitry 50 and the antenna assembly 40 are not limited to these frequency bands and the satellite 20 may be configured to operate at a different frequency band.
Referring now to
Another advantage of the illustrated antenna assembly 40 is that wide scan angle performance is not sacrificed as a result of the compact geometry. TABLE 1 provides performance parameters for the main reflector 44 positioned at broadside, i.e., no scanning. Taking into account antenna efficiencies between an operating frequency of 17.7 to 30 Ghz, the net antenna gain is expected to vary between 32.4 to 36.6 dB.
The antenna assembly 40 produces an optically focused reflector antenna system. An optically focused arrangement is maintained as an antenna beam is scanned in elevation and azimuth, resulting in good antenna performance over the entire scan range.
TABLE 2 provides performance parameters for the splash plate 46 positioned for a wide scan of 60 degrees from the antenna boresight (approximately 20 beamwidths of scan). Taking into account antenna efficiencies between the operating frequency of 17.7 to 30 Ghz, the net antenna gain is expected to vary between 28.5 to 32.2 dB. The difference between broadside and the maximum scan range for the net gain is −3.9 dB to −4.4 dB. Antenna performance is relatively stable over the wide angle scan range.
The difference between broadside and the maximum scan range for the net gain is −3.9 dB to −4.4 dB. Antenna performance is relatively stable over the scan angle range.
In addition, the antenna assembly may be configured to scan over 10 degrees of bandwidth. This corresponds to 20 scans to cover the +/−60 degree scan range. The scan ranges for the antenna assembly 40 are illustrative and are not to be limiting.
Referring now to the flowchart 200 illustrated in
Many modifications and other embodiments of the invention will come to the mind of one skilled in the art having the benefit of the teachings presented in the foregoing descriptions and the associated drawings. Therefore, it is understood that the invention is not to be limited to the specific embodiments disclosed, and that modifications and embodiments are intended to be included within the scope of the appended claims.
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20020140617 | Luly | Oct 2002 | A1 |
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Borisov et al. “Mirror antenna with mechanical beam scanning” Source: Izvestiya Vysshikh Uchebnykh Zavedenij. Radioelektronika, v 45, n 3, p. 68-70, 2002 Language: Russian. |
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Number | Date | Country | |
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20170040684 A1 | Feb 2017 | US |