A connection arrangement for forming a component carrier structure is disclosed. The connection arrangement includes a first electrically conductive connection element and a second electrically conductive connection element. The first connection element and the second connection element are configured such that, upon connecting the first connection element with the second connection element along a connection direction, a form fit is established between the first connection element and the second connection element that limits a relative motion between the first connection element and the second connection element in a plane perpendicular to the connection direction. A component carrier and a method of forming a component carrier structure are also disclosed.

A method of liquid assisted binding is provided. The method includes: forming a conductive pad on the substrate; placing a micro device on the conductive pad, such that the micro device is in contact with the conductive pad in which the micro device comprises an electrode facing the conductive pad; forming a liquid layer on the micro device and the substrate after said placing, such that a part of the liquid layer penetrates between the micro device and the conductive pad, and the micro device is gripped by a capillary force produced by said part of the liquid layer; and evaporating the liquid layer such that the electrode is bound to the conductive pad and is in electrical connection with the conductive pad.

An information handling system printed circuit board includes solder pads that accept footprint compatible integrated circuits, such as charger integrated circuits that provide power with different choke circuit supporting components. Solder pads for supporting components include first and second conductive areas sized to accept a first supporting component, each of the first and second conductive areas including an intervening non-conductive area that manages positioning of a smaller second supporting component at solder reflow.

A method of liquid assisted binding is provided. The method includes: forming a conductive pad on the substrate; placing a micro device on the conductive pad, such that the micro device is in contact with the conductive pad in which the micro device comprises an electrode facing the conductive pad; forming a liquid layer on the micro device and the substrate after said placing, such that a part of the liquid layer penetrates between the micro device and the conductive pad, and the micro device is gripped by a capillary force produced by said part of the liquid layer; and evaporating the liquid layer such that the electrode is bound to the conductive pad and is in electrical connection with the conductive pad.

A method of restricting a micro device on a conductive pad is provided. The method includes: forming the conductive pad having a first lateral length on a substrate; forming a liquid layer on the conductive pad; and placing the micro device having a second lateral length over the conductive pad such that the micro device is in contact with the liquid layer and is gripped by a capillary force produced by the liquid layer between the micro device and the conductive pad, the micro device comprising an electrode facing the conductive pad, wherein the first lateral length is less than or equal to twice of the second lateral length.

There is provided a method which includes placing a component on a substrate and extending an alignment member through an opening in the substrate. Once the alignment member is extended through the opening, the component is moved to abut against the alignment member to align the component relative to the substrate. After the component is aligned relative to the substrate, the component is secured to the substrate and the alignment member is retracted through the opening.

Precisely aligned assemblies can be complex, time consuming, labor intensive, and expensive and a need exists for better alternatives. Systems and methods described herein yield high precision printed circuit board assemblies (PCBAs) that contain pre-built alignment features to address this need. The work of precisely locating components on the PCBA to a final position in the overall assembly is already built in to the board. Locating features are used to precisely position one or more components, such as optical components, electro optical components, or mechanical components in assemblies. The locating features may be used to constrain the positions of those components, such as by kinematic coupling, solder wetting dynamics, semiconductor cleaving, dicing, photolithographic techniques for etching, constant contact force, and advanced adhesive technology to result in optical level positioning that significantly improves or eliminates assembly alignment challenges.

Ball grid assembly (BGA) bumping solder is formed on the back side of a laminate panel within a patterned temporary resist. Processes such as singulation and flip chip module assembly are conducted following BGA bumping with the temporary resist in place. The resist is removed from the back side of the singulated laminate panel prior to card assembly. Stand-off elements having relatively high melting points can be incorporated on the BGA side of the laminate panel to ensure a minimum assembly solder collapse height. Alignment assemblies are formed on the socket-facing side of an LGA module using elements having relatively high melting points and injected solder.

One or more channels are provided in the surface of a conductive layer of a PCB substrate in an area on which a component is to be placed. The channels can help reduce or prevent shifting of the component during reflow soldering through surface tension/capillary forces of the solder paste material in the channels. Such channels also can be used, for example, by an image processing system to facilitate accurate positioning and/or alignment of the component. The image processing system can use the location of the channels alone, or in combination with other features such as a solder mask or other alignment marks, to position and/or align the component with high accuracy.

The present application is directed to a filter and methods of transmitting a signal through the filter. The filter includes a pair of adjoined blocks of dielectric material. A top surface of each block has a conductive patterned region. The filter also includes plural spaced apart through-holes extending through each block from the top surface to a bottom surface. The through-holes are partially surrounded by the patterned region. The filter also includes a peripheral window disposed between the adjoined blocks to permit a coupling between adjacent through-holes of the adjoined blocks. The filter also includes an in-line window and/or a crenellation located within a block of the pair of blocks and disposed between adjacent through-holes of the block to limit or tune coupling between the adjacent through-holes. The application is also directed to a system including a printed circuit board and a filter.