Abstract: The present invention is a pole-mountable shroud assembly enclosing one or more wireless telecommunications transceivers and antennas, which extend from the pole and are rigidly attached to the pole by one or more transceiver brackets. A generally circular stationary panel is rigidly attached to the pole, and a generally annular, segmented jacked panel is attached to the pole at a vertical separation distance from the stationary panel. A panel jack, such as a screw or spring jack, connects the jacked panel to the pole so that the panel separation distance and the jacked panel circumference are adjustable. A very thin (not more than one-tenth the minimum transmission wavelength) fabric membrane shroud wraps around the circumference of the two panels, so as to form a generally cylindrical shroud enclosure which surrounds the transceivers/antennas. The panel jack is operative to tension, both vertically and radially, the fabric membrane shroud around the shroud enclosure.

Abstract: The present invention is a pole-mountable shroud assembly enclosing one or more wireless telecommunications transceivers and antennas, which extend from the pole and are rigidly attached to the pole by one or more transceiver brackets. A generally circular stationary panel is rigidly attached to the pole, and a generally annular, segmented jacked panel is attached to the pole at a vertical separation distance from the stationary panel. A panel jack, such as a screw or spring jack, connects the jacked panel to the pole so that the panel separation distance and the jacked panel circumference are adjustable. A very thin (not more than one-tenth the minimum transmission wavelength) fabric membrane shroud wraps around the circumference of the two panels, so as to form a generally cylindrical shroud enclosure which surrounds the transceivers/antennas. The panel jack is operative to tension, both vertically and radially, the fabric membrane shroud around the shroud enclosure.

Abstract: The present invention is a pole-mountable shroud assembly enclosing one or more wireless telecommunications transceivers and antennas. The shroud assembly is attached to the pole by a pole bracket, which is an elongated rectangular prism frame. The outer face of the pole bracket is open, so as to expose at least one intake fan supported by the pole bracket. The top and bottom ends of the pole bracket support top and bottom panels, respectively, with the bottom panel having multiple holes and/or vents, through which the intake fan(s) draw ambient air to cool the transceivers. A jacking means, such as a screw jack, connects the bottom panel to the pole bracket bottom end so that the panel separation distance is adjustable. A very thin (not more than one-tenth the minimum transmission wavelength) fabric membrane wraps around the top and bottom panels to the longitudinal sides of the pole bracket, so as to form a generally rectangular prism shaped shroud enclosure which surrounds the transceivers/antennas.

Abstract: A telecommunications network comprises multiple nodes linked by line-of-sight (LOS) signals. Directional antennas are located outside concealment screens to avoid attenuation through multiple screening layers. Directional LOS aiming between nodes is accomplished by fully rotable radomes within which multiple antennas are contained or by rotation of gimbaled antennas within the radomes. Network architecture is configured for both azimuthal and elevational LOS antenna aiming, with redundancy to re-route around disabled nodes.

Abstract: A telecommunications network comprises multiple nodes linked by line-of-sight (LOS) signals. Directional antennas are located outside concealment screens to avoid attenuation through multiple screening layers. Directional LOS aiming between nodes is accomplished by fully rotable radomes within which multiple antennas are contained or by rotation of gimbaled antennas within the radomes. Network architecture is configured for both azimuthal and elevational LOS antenna aiming, with redundancy to re-route around disabled nodes.

Abstract: A method is disclosed for alternately covering and exposing feed cables to a wireless telecommunications antenna from a pole-mounted RF source. The method deploys a resiliently stretchable tubular shroud, which has a proximal opening attached near the top of the pole and a distal opening alternately attachable to a section of the antenna proximate to the cable connections or to a section of the pole below the proximal shroud opening. In the former configuration, the shroud covers and protects the feed cables, while in the latter configuration, the retracted shroud exposes the cables for repair, maintenance, replacement and/or inspection operations.

Abstract: An RF antenna structure conceals RF equipment, comprising transmission, receiver and/or transceiver radios, underground in a foundation chamber than supports the antenna mast or pole. The RF equipment is attached to a pneumatic cylinder which, when pressurized, lifts the radios above the foundation grade, where they can be readily accessed for maintenance, repair and/or replacement. In the unpressurized configuration, the pneumatic cylinder conceals the RF equipment underground, where it is secure and not visually obtrusive. An alternative cylindrical lifting means, such as a hydraulic cylinder or a cylindrical electro-mechanical actuator, can be substituted for the pneumatic cylinder.

Abstract: A pole structure has been modified to house the antenna arrays, radios and electrical apparatus associated with a wireless node or micro-cell site. The upper part of the pole, which can be configured as a light, utility, sign or flag pole, supports for encloses the node's antenna arrays. The lower portion of the pole, having a larger diameter than the upper part, encloses a street modular lattice core structure, on which the radios are supported on removable x-frame modules for ease of maintenance with optimal air flow and heat dissipation. A rolled steel outer skin/sheath of the lower pole has multiple hinged doors to provide ready access to the lattice core and the radios.

Abstract: A pole structure has been modified to house the antenna arrays, radios and electrical apparatus associated with a wireless node or micro-cell site. The upper part of the pole, which can be configured as a light, utility, sign or flag pole, supports for encloses the node's antenna arrays. The lower portion of the pole, having a larger diameter than the upper part, encloses a street modular lattice core structure, on which the radios are supported on removable x-frame modules for ease of maintenance with optimal air flow and heat dissipation. A rolled steel outer skin/sheath of the lower pole has multiple hinged doors to provide ready access to the lattice core and the radios.

Abstract: A banner support supports a banner or flag unfurled on the pole. When a preset trigger wind load is exceeded, the banner bracket rotates away from the direction of the wind so as to limit the stress on the pole. The mechanism which enables bracket rotation comprises a disk-shaped cam with a spring-loaded plunger extending from the support arm that biases a cam follower into a proximal cam detent. Subject to the restraint of the cam follower, the cam rotates around a transversely axial cam shaft connected to the support arm. The cam is rigidly attached to the banner bracket, which rotates along with the cam. When the preset wind load is exceeded, the cam follower is forced out of the cam detent, allowing the cam and the connected banner bracket to rotate away from the wind direction. As the banner turns away from the wind, the wind stress decreases, allowing the spring plunger to force the cam follower back into the cam detent, thereby restoring the banner to its rest position.