Systems and methods are disclosed herein for printed cavities for computational microwave imaging and methods or use. According to an aspect, an imaging system includes a printed cavity having a layer having a first surface and a second surface. The printed cavity defines multiple apertures that extend between the first surface and the second surface. The printed cavity also includes a substrate being attached to the first surface of the layer. The substrate is also configured to be fed a guided wave that excites the apertures to produce a radiation pattern for illuminating a scene. The imaging system also include one or more antennas configured to generate a signal for imaging based on the illuminated scene.

A method for measuring a residual DC voltage in a liquid crystal device including an active region having a plurality of liquid crystal capacitors and a plurality of TFTs, and a non-active region positioned outside the active region and having at least one monitoring capacitor, in which the plurality of liquid crystal capacitors and the at least one monitoring capacitor include a liquid crystal layer. The method includes: generating a V-I curve by applying a positive and negative symmetrical triangular wave voltage measuring, in the V-I curve, a voltage Vmax having a maximum absolute value where a current value reaches a positive maximum value or minimum value, and a voltage Vmin having a maximum absolute value where a current value reaches a negative minimum value or maximum value, and measuring one-half of the sum of the voltage Vmax and the voltage Vmin as the residual DC voltage.

Multiband guiding structures for antennas and methods for using the same are described. In one embodiment, an antenna comprises: an antenna aperture with radio-frequency (RF) radiating antenna elements; and a center-fed, multi-band wave guiding structure coupled to the antenna aperture to receive a feed wave in two different frequency bands and propagate the feed wave to the RF radiating antenna elements of the antenna aperture.

Techniques for motion mitigation for uplink power control are disclosed. In one embodiment, a method for use in a satellite communication system comprises: generating a power margin associated with motion of an antenna of a satellite terminal; and generating a first power limit representing a maximum transmit power for the antenna based, at least in part, on the power margin.

A method for manufacturing a scanning antenna with a plurality of antenna units arrayed therein, the scanning antenna including a TFT substrate including a first dielectric substrate, a TFT, gate bus lines, source bus lines, and a plurality of patch electrodes, a slot substrate including a second dielectric substrate and a slot electrode including a plurality of slots disposed corresponding to the plurality of patch electrodes, a liquid crystal layer, and a reflective conductive plate, includes a step (a) of depositing a first conductive film containing copper on a first main surface of the second dielectric substrate, a step (b) of, after step (a), bringing the first conductive film into contact with an atmosphere to form an oxide film on a surface of the first conductive film, and a step (c) of, after step (b), depositing a second conductive film containing copper on the oxide film.

A scanning antenna includes a TFT substrate including a plurality of TFTs supported by a first dielectric substrate and a plurality of patch electrodes, a slot substrate including a slot electrode supported by a second dielectric substrate, a liquid crystal layer provided between the TFT substrate and the slot substrate, and a reflective conductive plate disposed opposing the second dielectric substrate across a dielectric layer. The slot electrode includes a plurality of slots disposed corresponding to the plurality of patch electrodes, each patch electrode is connected to a drain of the corresponding TFT, the slot electrode includes Cu layers, and lower metal layers and/or an upper metal layer, and the lower metal layer and/or the upper metal layer decrease about a half or more of a tensile stress of the Cu layer.

A method and apparatus for using Euclidean modulation in an antenna are disclosed. In one embodiment, a method for controlling an antenna comprises mapping a desired modulation to achievable modulation states, mapping modulation values associated with the achievable modulation states to one or more control parameters, and controlling radio frequency (RF) radiating antenna elements using the one or more control parameters to perform beam forming.

The disclosed structures and methods are directed to antenna systems configured to transmit and receive a wireless signal in and from different directions. A switchable lens antenna has excitation ports radiating radio-frequency (RF) wave into a parallel-plate waveguide structure, and a frequency selective structure (FSS). The antenna presented herein is configured to operate in two modes depending on an initial steering angle of the RF wave propagating in the parallel-plate waveguide structure. When the initial steering angle is about or less than a threshold steering angle, FSS is OFF due to its stubs being electrically disconnected from the parallel-plate waveguide structure. When the initial steering angle is higher than the threshold, FSS is ON with stubs being electrically connected to the parallel-plate waveguide structure. When ON, FSS provides phase variance to the RF wave propagating in the parallel-plate waveguide structure and increases steering angle of the RF wave.

A liquid crystal panel of a scanning antenna includes a TFT substrate provided with a first dielectric substrate, a TFT supported by the first dielectric substrate, a gate bus line, a source bus line, and a patch electrode; a slot substrate provided with a second dielectric substrate, and a slot electrode that is formed on a first main surface of the second dielectric substrate and includes a slot arranged so as to correspond to the patch electrode; and a liquid crystal layer provided between the TFT substrate and the slot substrate. One of the TFT substrate and the slot substrate includes a projecting layer formed of resin and disposed on the liquid crystal layer side of the patch electrode or the slot electrode in a region surrounded by a sealing portion. The projecting layer is arranged so as not to overlap the patch electrode or the slot.

A liquid crystal panel P according to the present invention includes: a liquid crystal layer LC; and a pair of first and second substrates 100 and 200 disposed with the liquid crystal layer LC interposed therebetween and including an alignment film M formed on a surface of each of the first and second substrates facing the liquid crystal layer, or a surface of any one of the first and second substrates facing the liquid crystal layer. The alignment film M contains a carboxyl group-containing polymer containing a carboxyl group. The liquid crystal compound constituting the liquid crystal layer LC contains at least one selected from the group consisting of a cyano group, a heterocyclic ring, —OCF.sub.2—, a carbon-carbon triple bond and a trifluoromethyl group, contains an aliphatic alkyl group at a terminal thereof, and does not contain an isothiocyanate group. Antenna units are arranged.