Patent application number | Description | Published |
20110123783 | MULTILAYER BUILD PROCESSSES AND DEVICES THEREOF - A process to form devices may include forming a seed layer on and/or over a substrate, modifying a seed layer selectively, forming an image-wise mold layer on and/or over a substrate and/or electrodepositing a first material on and/or over an exposed conductive area. A process may include selectively applying a temporary patterned passivation layer on a conductive substrate, selectively forming an image-wise mold layer on and/or over a substrate, forming a first material on and/or over at least one of the exposed conductive areas and/or removing a temporary patterned passivation layer. A process may include forming a sacrificial image-wise mold layer on a substrate layer, selectively placing one or more first materials in one or more exposed portions of a substrate layer, forming one or more second materials on and/or over a substrate layer and/or removing a portion of a sacrificial image-wise mold layer. | 05-26-2011 |
20110181376 | WAVEGUIDE STRUCTURES AND PROCESSES THEREOF - An apparatus may include one or more conductive surfaces, waveguide structures and/or ports. One or more waveguide structures may include a portion disposed above a conductive surface, an outer conductor, and/or an inner conductor. A first portion of an outer conductor may be connected to a conductive surface. A port end of an outer conductor may be connected to an outer conductor port. An inner conductor may be disposed inside and spaced apart from an outer conductor. An inner conductor port may be connected to an inner conductor. An inner conductor of two or more waveguide structures may be connected to each other. A conductive surface may include at least one aperture portion, which may have a width substantially similar to the width of a waveguide structure. A substrate may be disposed between one or more waveguide structures and a conductive surface for a substantial portion of a waveguide structure. | 07-28-2011 |
20110181377 | THERMAL MANAGEMENT - A transmission line structure, a transmission line thermal manager and/or process thereof. A transmission line thermal manager may include a thermal member. A thermal member may be configured to form a thermal path, for example away from one or more inner conductors of a transmission line. A part of a thermal member may be formed of an electrically insulative and thermally conductive material. One or more inner conductors may be spaced apart from one or more outer conductors in a transmission line. A transmission line and/or a transmission line thermal manager may be configured to maximize a signal through a system, for example by modifying the geometry of one or more transmission line conductors and/or of a thermal manager. | 07-28-2011 |
20120062335 | THREE-DIMENSIONAL MICROSTRUCTURES - An apparatus comprising a first power combiner/divider network and a second power combiner/divider network. The first power combiner/divider network splits a first electromagnetic signal into split signals that are connectable to signal processor(s). The second power combiner/divider network combines processed signals into a second electromagnetic signal. The apparatus includes a three-dimensional coaxial microstructure. | 03-15-2012 |
20130016022 | Hollow Core Coaxial Cables and Methods of Making the SameAANM Heiks; NoelAACI RadfordAAST VAAACO USAAGP Heiks; Noel Radford VA USAANM Sherrer; DavidAACI RadfordAAST VAAACO USAAGP Sherrer; David Radford VA US - Disclosed and claimed herein is a hollow core coaxial cable, having a dielectric capillary with an inside wall and an outside wall, an inner conductive layer on the inside wall of the hollow core coaxial cable and an outer conductive layer on the outside wall of the hollow core coaxial cable, the conductive layers may be patterned. Further disclosed is a method of making the hollow core coaxial cable. Further disclosed are holey fiber coaxial cables, having a holey fiber capillary having an inside wall and an outside wall, an inner conductive layer on the inside wall of the hollow core coaxial cable and an outer conductive layer on the outside wall of the hollow core coaxial cable, the conductive layers may be patterned. | 01-17-2013 |
20130333820 | MULTILAYER BUILD PROCESSES AND DEVICES THEREOF - A process to form devices may include forming a seed layer on and/or over a substrate, modifying a seed layer selectively, forming an image-wise mold layer on and/or over a substrate and/or electrodepositing a first material on and/or over an exposed conductive area. A process may include selectively applying a temporary patterned passivation layer on a conductive substrate, selectively forming an image-wise mold layer on and/or over a substrate, forming a first material on and/or over at least one of the exposed conductive areas and/or removing a temporary patterned passivation layer. A process may include forming a sacrificial image-wise mold layer on a substrate layer, selectively placing one or more first materials in one or more exposed portions of a substrate layer, forming one or more second materials on and/or over a substrate layer and/or removing a portion of a sacrificial image-wise mold layer. | 12-19-2013 |
20140015623 | COAXIAL TRANSMISSION LINE MICROSTRUCTURES AND METHODS OF FORMATION THEREOF - Provided are coaxial transmission line microstructures formed by a sequential build process, and methods of forming such microstructures. The microstructures include a transition structure for transitioning between the coaxial transmission line and an electrical connector. The microstructures have particular applicability to devices for transmitting electromagnetic energy and other electronic signals. | 01-16-2014 |
20160072171 | COAXIAL TRANSMISSION LINE MICROSTRUCTURES AND METHODS OF FORMATION THEREOF - Provided are coaxial transmission line microstructures formed by a sequential build process, and methods of forming such microstructures. The microstructures include a transition structure for transitioning between the coaxial transmission line and an electrical connector. The microstructures have particular applicability to devices for transmitting electromagnetic energy and other electronic signals. | 03-10-2016 |
Patent application number | Description | Published |
20140266515 | Coaxial Waveguide Microstructures Having an Active Device and Methods of Formation Thereof - Provided are coaxial waveguide microstructures. The microstructures include a substrate and a coaxial waveguide disposed above the substrate. The coaxial waveguide includes: a center conductor; an outer conductor including one or more walls, spaced apart from and disposed around the center conductor; one or more dielectric support members for supporting the center conductor in contact with the center conductor and enclosed within the outer conductor; and a core volume between the center conductor and the outer conductor, wherein the core volume is under vacuum or in a gas state. Also provided are methods of forming coaxial waveguide microstructures by a sequential build process and hermetic packages which include a coaxial waveguide microstructure. | 09-18-2014 |
20140364015 | BATCH FABRICATED MICROCONNECTORS - Connectors and interconnects for high power connectors which may operate at frequencies up to approximately 110 GHz and fabrication methods thereof are provided. | 12-11-2014 |
20150184998 | DEVICE PACKAGE AND METHODS FOR THE FABRICATION AND TESTING THEREOF - Provided are methods of forming sealed via structures. One method involves: (a) providing a semiconductor substrate having a first surface and a second surface opposite the first surface; (b) forming a layer on the first surface of the substrate; (c) etching a via hole through the substrate from the second surface to the layer, the via hole having a first perimeter at the first surface; (d) forming an aperture in the layer, wherein the aperture has a second perimeter within the first perimeter; and (e) providing a conductive structure for sealing the via structure. Also provided are sealed via structures, methods of detecting leakage in a sealed device package, sealed device packages, device packages having cooling structures, and methods of bonding a first component to a second component. | 07-02-2015 |
20150327410 | DEVICE PACKAGE AND METHODS FOR THE FABRICATION THEREOF - A microwave assembly having a substrate comprising a microwave device; said device having a die, a first layer having a dielectric constant between about 1.00 and about 1.45 and a thickness between about 0.05 and about 2 mm along with one or more layers chosen from an absorbing layer, an EMI blocking layer, a layer comprising conductive material or a metal cover. | 11-12-2015 |