Abstract: An optical port apparatus includes a housing having oppositely disposed first and second housing surfaces and a housing body extending therebetween. A housing aperture extends about a central axis of the housing body. A groove surrounds the housing aperture. The groove extends partially through the housing body and has a bottom groove surface spaced from the second housing surface by a groove side wall. A shelf is located between the groove and the housing aperture. A gasket is located in the groove adjacent the bottom groove surface. The gasket surrounds the housing aperture. A window is located across the housing aperture in contact with the shelf. An elastomeric adhesive is located in the groove between the groove side wall and at least one of the window and the gasket. A bezel is fastened to the second housing surface adjacent the groove.

Abstract: An optical port apparatus includes a housing having oppositely disposed first and second housing surfaces and a housing body extending therebetween. A housing aperture extends about a central axis of the housing body. A groove surrounds the housing aperture. The groove extends partially through the housing body and has a bottom groove surface spaced from the second housing surface by a groove side wall. A shelf is located between the groove and the housing aperture. A gasket is located in the groove adjacent the bottom groove surface. The gasket surrounds the housing aperture. A window is located across the housing aperture in contact with the shelf. An elastomeric adhesive is located in the groove between the groove side wall and at least one of the window and the gasket. A bezel is fastened to the second housing surface adjacent the groove.

Abstract: A collapsible garment hanger including a hook element attached to a fixed arm, a sliding arm with a longitudinally oriented slot, a crosspiece extending through the slot, attaching the sliding arm slidably to the fixed arm. When the distal end of the fixed arm tilts upward, gravity will cause the sliding arm to slide away from the distal end of the fixed arm. Whenever the distal end of the fixed arm tilts downward, gravity will cause the sliding arm to slide towards the distal end of the fixed arm. The collapsible garment hanger can also manually slide away from or towards the distal end of the fixed arm. An offset spacing between the outer tip of the sliding arm when it is in the collapsed position and the opposing offset portion of the hanger determines the size of neck of garment through which the hanger will fit.

Abstract: A radio frequency aperture comprising a plurality of insulating layers disposed in a stack, each layer including an array of conductive regions, the conductive regions being spaced from adjacent conductive regions. Also disclosed is method of bending or steering radio frequency waves impinging an antenna. The method includes disposing a plurality of insulating layers arranged in a stack between a source of the radio frequency waves and the antenna, wherein each insulating layer includes an array of conductive regions, the conductive regions being spaced from adjacent conductive regions and forming capacitive elements. The capacitance of the capacitive elements in the plurality of insulating layers is adjusted as a function of their location in the plurality of insulating layers.

Abstract: The system (10) includes a first mechanism (12) for receiving electromagnetic energy of a first wavelength from the scene (28) and providing electromagnetic energy of a second wavelength shorter than the first wavelength. A second mechanism (14) measures variations of the electromagnetic energy of the second wavelength over a predetermined area. The system is a millimeter wave imaging system (10). The first mechanism (12) includes a lens (12) having an index of refraction substantially greater than 1. The lens (12) is opaque to infrared electromagnetic energy and made of alumina, plastic, or other material having a relatively high index of refraction. The second mechanism (24) includes and array of bolometers (24) positioned parallel to an output aperture (24) of the lens and within a distance of the output aperture (24) that is much smaller than the second wavelength.

Abstract: A high-power microwave/mm-wave oscillator is filled with an ionizable gas at a pressure of about 1-20 mTorr, into which an electron beam is injected at a high current density of at least about 1 amp/cm.sup.2, but typically 50-100 A/cm.sup.2. A plasma is formed which inhibits space-charge blowup of the beam, thereby eliminating the prior requirement of a magnet system to control the beam. The system functions as a slow-wave tube to produce narrow-band microwaves for a gas pressure of about 1-5 mTorr, and as a plasma wave tube to produce broadband microwave/mm-wave radiation for a gas pressure of about 10-20 mTorr.