A lightweight and portable space frame antenna includes a first plurality of reflector panels and a second plurality of reflector panels each being sized and configured such that each one of said first plurality of reflector panels can be nested inside a corresponding one of said second plurality of reflector panels, thereby defining a nested pairing; a plurality of helical cam latching devices for joining together each of the first and second pluralities of reflector panels; a reflector hub consisting of two pieces, wherein the first and second pluralities of reflector panels are mounted on the reflector hub to form a parabolic reflector; a foldable positioner for supporting the parabolic reflector; a telescoping actuator that is structured and disposed for providing elevation adjustment and may be selectively disconnected from the parabolic reflector; and an elevation-azimuth bar that is structured and disposed for providing azimuth adjustment through a bearing-free azimuth rotation.

A lightweight and portable space frame antenna includes a first plurality of reflector panels and a second plurality of reflector panels each being sized and configured such that each one of said first plurality of reflector panels can be nested inside a corresponding one of said second plurality of reflector panels, thereby defining a nested pairing; a plurality of helical cam latching devices for joining together each of the first and second pluralities of reflector panels; a reflector hub consisting of two pieces, wherein the first and second pluralities of reflector panels are mounted on the reflector hub to form a parabolic reflector; a foldable positioner for supporting the parabolic reflector; a telescoping actuator that is structured and disposed for providing elevation adjustment and may be selectively disconnected from the parabolic reflector; and an elevation-azimuth bar that is structured and disposed for providing azimuth adjustment through a bearing-free azimuth rotation.

A method and system for reflecting a radar signal. First, an event for a platform is detected. Next, a number of decoy units is launched from a launcher system for the platform, wherein a decoy unit comprises an inflatable radar decoy and an inflator cartridge configured to inflate the inflatable radar decoy. Then, the inflatable radar decoy is inflated using the inflator cartridge after launching the decoy unit from the launcher system for the platform.

The invention is directed to deployable reflectarray antenna structure. In one embodiment, the deployable reflectarray antenna structure includes a pair of flexible electrical elements, a feed antenna, and a deployment mechanism that employs a plurality of tapes to respectively transition the pair of flexible electrical elements from an undeployed state in which the elements are folded towards a deployed state in which the deployment mechanism and electrical elements cooperate to form a reflectarray and a subreflector of a reflectarray antenna structure. Further, the deployment mechanism also operates to position the reflectarray and subreflector relative to one another and to the feed antenna so as to realize a reflectarray antenna structure.

The invention is directed to deployable reflectarray antenna structure. In one embodiment, the deployable reflectarray antenna structure includes a pair of flexible electrical elements, a feed antenna, and a deployment mechanism that employs a plurality of tapes to respectively transition the pair of flexible electrical elements from an undeployed state in which the elements are folded towards a deployed state in which the deployment mechanism and electrical elements cooperate to form a reflectarray and a subreflector of a reflectarray antenna structure. Further, the deployment mechanism also operates to position the reflectarray and subreflector relative to one another and to the feed antenna so as to realize a reflectarray antenna structure.

An expandable antenna includes: a plurality of ribs arranged with a regulated angular pitch at an outer circumferential portion of a hub; and a metal mesh installed between the plurality of adjacent ribs, wherein each of the plurality of ribs is formed in a horizontally elongated thin flat plate shape with elasticity, and a segment to which the metal mesh is attached is formed in a parabolic shape. A flat plane of each of the plurality of ribs is arranged so as to be substantially parallel to a central axis of the hub. The object of the present invention is to provide the expandable antenna which can be easily expanded in outer space with a simple structure and can realize a desired shape after expansion.

An expandable antenna includes: a plurality of ribs arranged with a regulated angular pitch at an outer circumferential portion of a hub; and a metal mesh installed between the plurality of adjacent ribs, wherein each of the plurality of ribs is formed in a horizontally elongated thin flat plate shape with elasticity, and a segment to which the metal mesh is attached is formed in a parabolic shape. A flat plane of each of the plurality of ribs is arranged so as to be substantially parallel to a central axis of the hub. The object of the present invention is to provide the expandable antenna which can be easily expanded in outer space with a simple structure and can realize a desired shape after expansion.

The invention is directed to deployable reflectarray antenna structure. In one embodiment, the deployable reflectarray antenna structure includes a pair of flexible electrical elements, a feed antenna, and a deployment mechanism that employs a plurality of tapes to respectively transition the pair of flexible electrical elements from an undeployed state in which the elements are folded towards a deployed state in which the deployment mechanism and electrical elements cooperate to form a reflectarray and a subreflector of a reflectarray antenna structure. Further, the deployment mechanism also operates to position the reflectarray and subreflector relative to one another and to the feed antenna so as to realize a reflectarray antenna structure.

The invention is directed to deployable reflectarray antenna structure. In one embodiment, the deployable reflectarray antenna structure includes a pair of flexible electrical elements, a feed antenna, and a deployment mechanism that employs a plurality of tapes to respectively transition the pair of flexible electrical elements from an undeployed state in which the elements are folded towards a deployed state in which the deployment mechanism and electrical elements cooperate to form a reflectarray and a subreflector of a reflectarray antenna structure. Further, the deployment mechanism also operates to position the reflectarray and subreflector relative to one another and to the feed antenna so as to realize a reflectarray antenna structure.

Antenna system includes an elongated antenna feed tower structure having a tower base at one end which includes a plurality of feet arranged to align with a plurality of predetermined structural mounting points associated with a space vehicle bus. The antenna system also includes a deployable reflector assembly comprising a hub ring. The hub ring includes a reflector deployment mechanism around which a plurality of reflector ribs are disposed. The hub ring is advantageously arranged to engirdle the feed tower assembly. As such, the central aperture is configured to receive the feed tower assembly therein after the feed tower has already been mounted to the space vehicle.