Abstract: A packaging substrate, a packaging structure, an electronic device and a manufacturing method, and pertain to the field of chip packaging technologies. The packaging substrate includes a body including metal cabling. The body includes a first surface, a second surface and a side surface. The side surface is connected to the first surface and second surface. The first surface includes many first connection structures. The second surface includes second connection structures. The side surface includes third connection structures. A part of the first connection structures are connected to the second connection structures by using the metal cabling. The other part of the first connection structures are connected to the third connection structures by using the metal cabling. When the same total quantity of pins need to be disposed, a part of the pins are transferred to the side surface of the body, with less pins at the second surface.

Abstract: A package structure includes a substrate, a die, an adhesive layer, a dam structure, and an encapsulant. The die is disposed on the substrate. The adhesive layer is disposed between the substrate and the die. The adhesive layer has a curved surface. The dam structure is disposed on the substrate and surrounded by the adhesive layer. The encapsulant encapsulates the die.

Abstract: This publication discloses an electronic module, comprising a first conductive pattern layer and a first insulating-material layer on at least one surface of the first conductive pattern layer, at least one opening in the first insulating-material layer that extends through the first insulating-material layer, a component having a contact surface with contact terminals, the component being arranged at least partially within the opening with its contact terminals electrically coupled to the first conductive pattern layer, a second insulating-material layer provided on the first insulating-material layer, and a conductive pattern embedded between the first and second insulating material layers. This publication additionally discloses a method for manufacturing an electronic module.

Abstract: An electronic device including an interposer is provided.

Abstract: A coil component includes a body part containing a magnetic material, a coil part disposed in the body part, and an electrode part disposed on the body part. The coil part includes a support member, a first coil layer disposed on at least one surface of the support member, a first insulating layer stacked on at least one surface of the support member and covering the first coil layer, and a second coil layer disposed on the first insulating layer. The first and second coil layers are electrically connected to each other, and the second coil layer has a larger number of coil turns than the first coil layer. Additionally or alternatively, a conductor of the first coil layer has an aspect ratio less than 1. Methods of manufacturing such coil components are also provided.

Abstract: A coil component includes a body part containing a magnetic material, a coil part disposed in the body part, and an electrode part disposed on the body part. The coil part includes a support member, a first coil layer disposed on at least one surface of the support member, a first insulating layer stacked on at least one surface of the support member and covering the first coil layer, and a second coil layer disposed on the first insulating layer. The first and second coil layers are electrically connected to each other, and the second coil layer has a larger number of coil turns than the first coil layer. Additionally or alternatively, a conductor of the first coil layer has an aspect ratio less than 1. Methods of manufacturing such coil components are also provided.

Abstract: Process for the production of a component of valves, of fittings or of tap assemblies, including steps of providing a metal substrate, (electro-)depositing a first layer of copper on at least a portion of the metal substrate, and (electro-)depositing, on at least a portion of the first layer of copper and in direct contact therewith, a second shiny layer of chrome to obtain said component. A valve or tap assembly component made according to the aforesaid method.

Abstract: A junction structure for electronic device having an excellent bonding strength is provided. A junction structure for electronic device in accordance with one aspect of the present invention includes a first metal layer containing nickel and a second metal layer containing gold, tin, and nickel, while the second metal layer includes an AuSn eutectic phase.

Abstract: A wiring board comprises an insulating substrate; and a heat-transfer member disposed inside the insulating substrate. The insulating substrate comprises an upper surface and a recess formed in the upper surface, the upper surface including a first mounting region for a first electronic component, and a second mounting region for a second electronic component which is provided in the recess. The heat-transfer member is disposed inside the insulating substrate so as to overlap the first mounting region and the second mounting region as seen in a plan view, and, part of the heat-transfer member is exposed in the recess.

Abstract: The present disclosure relates generally to the field of static dissipative coatings. More specifically, the present disclosure relates to the methods of making static dissipative, preferably non-chromium-containing, coatings comprising carbon nanotubes, the coatings themselves, and structures comprising such coatings.

Abstract: A micro-electro-mechanical system (MEMS) microphone package is provided in the present disclosure. The MEMS microphone package includes a circuit board, an electromagnetic shielding cover mounted on the circuit board to define an accommodating space, electronic components received in the accommodating space and electrically connected to the circuit board, and a shielding ring covering a joint between the electromagnetic shielding cover and the circuit board. The shielding ring is configured for preventing electromagnetic waves from entering the accommodating space via the joint between the electromagnetic shielding cover and the circuit board.

Abstract: A housing includes a metal substrate, an adhesive layer formed on the metal substrate, and a resin film formed on the adhesive layer, the metal substrate, the adhesive layer and the resin film cooperatively form a cavity through a stamping process, an internal structure needed by the housing is formed in the cavity through an injection process, and the internal structure is formed on the resin film.

Abstract: Aspects of the disclosure pertain to a packaging structure configured for providing heterogeneous packaging of electronic components and a process for making same. The packaging structure includes a carrier substrate having a plurality of cavities formed therein. The packaging structure further includes a first die and a second die. The first die is at least substantially contained within a first cavity included in the plurality of cavities. The second die is at least substantially contained within a second cavity included in the plurality of cavities. The first die is fabricated via a first fabrication technology, and the second die is fabricated via a second fabrication technology, the second fabrication technology being different than the first fabrication technology. The packaging structure also includes electrical interconnect circuitry connected to (e.g., for electrically connecting) the first die, the second die and/or the carrier substrate.

Abstract: A module includes an insulating substrate having an upper surface as a principal surface, a lid member having an internal space with the insulating substrate, and bonded to the upper surface in a first surface, a device element housed in the internal space, a semiconductor element connected to a top surface, which forms the both sides of the lid member together with the first surface, using a resin adhesive, electrodes electrically connected to the device element, and disposed on an upper surface of the insulating substrate in an area other than the connection area with the lid member, and a projection section formed of the same member as the lid member on the upper surface in an area between the electrodes and the lid member in a plan view.

Abstract: According to an embodiment, there is an inductor, including: a magnetic core; a winding formed around the magnetic core; a first resin provided between turns of the winding; and a second resin covering the winding and the first resin, wherein the second resin has higher filler content than the first resin.

Abstract: A conductive-layer-integrated flexible printed circuit board includes: (A) an electromagnetic-shielding conductive layer; (B) an insulator film; and (C) a wiring-pattern-equipped film the electromagnetic-shielding conductive layer (A), the insulator film (B), and the wiring-pattern-equipped film (C) being laminated in this order, the insulator film (B) containing at least (a) a binder polymer and (b) spherical organic beads.

Abstract: In accordance with an embodiment of the present invention, a semiconductor device includes a leadframe having a plurality of leads and a die paddle and a semiconductor module attached to the die paddle of the leadframe. The semiconductor module includes a first semiconductor chip disposed in a first encapsulant. The semiconductor module has a plurality of contact pads coupled to the first semiconductor chip. The semiconductor device further includes a plurality of interconnects coupling the plurality of contact pads with the plurality of leads, and a second encapsulant disposed at the semiconductor module and the leadframe.

Abstract: Disclosed herein are a hybrid heat-radiating substrate including a metal core layer; an oxide insulating core layer that is formed in a thickness direction of the metal core layer to have a shape where the oxide insulating core layer is integrally formed with the metal core layer, an oxide insulating layer that is formed on one surface or both surfaces of the metal core layer, and a circuit layer that is configured to include first circuit patterns formed on the oxide insulating core layer and second circuit patterns formed on the oxide insulating layer, and a method of manufacturing the same.

Abstract: An electronics frame for a wired pipe drill string, including a housing arranged to be disposed within the wired pipe drill string. The housing includes a chamber formed therein and one or more electronic components disposed in the chamber. A shape memory element is disposed in the chamber. The shape memory element is transitionable in response to a transition stimulus between a first shape permitting positioning within the chamber and a second shape sealingly engagable with the housing to isolate the one or more electronic components from fluid. A method of isolating an electronic component is also included.

Abstract: Systems, processes, and manufactures are provided that employ a casing associated with an electrical component to provide some, most, substantially all or all electrical insulative protection necessary for the electrical component. This casing may be further employed with potting or other materials to supplement and add additional or different protections for the component. These additional protections can include additional insulative resistance, thermal protection, moisture protection and other buffers to and from the environment.

Abstract: Electronic devices may have housings in which components are mounted. Some of the components may be sensitive to moisture. Other components may be insensitive to moisture and may form openings in a device housing that allow moisture to escape from within the housing. Components may be mounted on substrates such as printed circuit board substrates. Moisture repelling layers and moisture attracting layers may be patterned to form channels and other structures that guide moisture away from sensitive components towards insensitive components. Moisture repelling and attracting layers may also be used to limit the lateral spread of a conformal coating layer when coating components.

Abstract: Electrical components such as integrated circuits may be mounted on a printed circuit board. To prevent the electrical components from being subjected to electromagnetic interference, radio-frequency shielding structures may be formed over the components. The radio-frequency shielding structures may be formed from a layer of metallic paint. Components may be covered by a layer of dielectric. Channels may be formed in the dielectric between blocks of circuitry. The metallic paint may be used to coat the surfaces of the dielectric and to fill the channels. Openings may be formed in the surface of the metallic paint to separate radio-frequency shields from each other. Conductive traces on the surface of the printed circuit board may be used in connecting the metallic paint layer to internal printed circuit board traces.

Abstract: A conformal coating comprising modified porous silica particles is disclosed. A porous silica particle, such as MCM-14 or SBA-15 is modified with a sulfur gettering functionality, such as a phosphine compound, covalently bonded to silicon atoms in the porous silica particle. The conformal coating comprising the modified porous silica particles may be applied to metallic wiring areas of a circuit component, with the sulfur gettering functionality preventing sulfur from atmospheric gasses from penetrating the conformal coating to the metallic wiring.

Abstract: A metal base circuit board, having an insulating layer with a linear expansion coefficient of 60 ppm per degree C. or higher and 120 ppm per degree C. or lower, a metal foil provided on one side of the insulating layer, comprising a metal material with a linear expansion coefficient of 10 ppm per degree C. or higher and 35 ppm per degree C. or lower, a circuit portion and a non-circuit potion having a linear expansion coefficient of 10 ppm per degree C. or higher and 35 ppm per degree C.

Abstract: Disclosed embodiments include a package having an electronic device disposed within a cavity formed by an enclosure that includes a sharp portion. The package may further include a photosensitive layer applied over the enclosure to provide a smooth portion that is adjacent to the sharp portion. Methods for manufacturing the package are also described. Other embodiments may be described and claimed.

Abstract: An electronics enclosure system includes a conductive polymer which includes electromagnetic interference shielding properties and produced to enhancing SE, reducing material costs, and improving thermal flow. “Parallel” hex shaped EMI waveguides placed in a honeycomb pattern are stacked in a staggered fashion with similar hex shaped EMI waveguides placed in a honeycomb pattern. The parallel hex shaped EMI waveguides extend into the interior and/or “cuts” into one or more sides of a an electronics enclosure. An EMI shielding polymer material, such as a coated polymer, or a nickel-fiber carbon polymer such as Primere® providing sufficient EMI shielding (or alternately a material that can be formed such as Superplastic Zinc) is used, having the result that the need for shielding gaskets are reduced, material usage is decreased, and thermal flow is greatly improved.

Abstract: Chip-scale packages and assemblies thereof are disclosed. The chip-scale package includes a core member of a metal or alloy having a recess for at least partially receiving a die therein and includes at least one flange member partially folded over another portion of the core member. Conductive traces extend from one side of the package over the at least one flange member to an opposing side of the package. Systems including the chip-scale packages and assemblies are also disclosed.

Abstract: A shell for an electronic device is provided. The shell includes a shell body and a pattern layer disposed on an outer surface of the shell body and formed by a curable material. The shell also includes a transparent protective layer disposed on an outer surface of the pattern layer.

Abstract: Disclosed is a power package for an electrical device of an Electronic Control Unit (ECU) in an Electric Power Steering (EPS) system, the power package including: a housing which is formed with an upper part and a lower part and is formed to be in a two-step structure where substrate layers are provided on each of the upper and lower parts; a Printed Circuit Board (PCB) layer which is provided on the lower part of the housing and has a path line formed thereon to flow a current; and an LTCC layer which is provided on the upper part of the housing, is connected to the PCB layer through wire-bonding, and is formed of a Low Temperature Co-fired Ceramics. The power package for an electrical device can expand areas of the PCB and LTCC layers, thereby enhancing freedom degree of design of the PCB and LTCC layers and reducing a size of the entire case.

Abstract: A housing comprise a decorative layer including a transparent base, a first conductive coating, an electrically conductive ink layer having a first electrical interface and a second conductive coating having a second electrical interface. The first conductive coating is formed on the base, the electrically conductive ink layer is laminated with and covers the first conductive coating, the second conductive coating is laminated between the electrically conductive ink layer and the outer surface of the substrate, the first electrical interface of the first conductive coating and the second electrical interface of the second conductive coating are electrically connected to a power source for creating an electrical field between the first conductive coating and the second conductive layer to make the electrically conductive ink layer present a pattern.

Abstract: Systems and methods for providing MEMS devices with integrated desiccant are provided. In one embodiment, a dry composition comprising desiccant is impact sprayed onto the backplate or substrate of a MEMS device, and becomes fused with the substrate. In another embodiment, the desiccant is impact sprayed such that the desiccant adheres to the impact sprayed surface. In yet another embodiment, the impact-sprayed surface is impregnated with the desiccant. In still another embodiment, the desiccant is combined with a suitable inorganic binder, then impact sprayed such that the desiccant adheres to the impact sprayed surface. In yet a further embodiment, the desiccant is micronized or pulverized into a powder of desired particle size, and then impact sprayed onto a surface. Thus, the desiccant particles or powder are fused onto the target surface through the impact spraying process.

Abstract: Particles having a relatively high porosity can be used in an information handling system or other information handling system. In one aspect, a portable information handling system can include an electrical circuit that can generate thermal energy during normal operation of the electrical circuit. The portable information handling system can also include a housing that includes a first material and particles having a porosity of at least 80%. In another aspect, an information handling system can include a housing that includes a material and a coating, wherein the coating includes a polymeric material and particles having a porosity of at least 80%. In another aspect, a process of forming an information handling system can include coating a surface of a housing, wherein the coating includes particles having a porosity of at least 80%, and placing an electrical circuit within the housing after coating the surface.

Abstract: An electronic device housing includes a substrate, a film structure, and a protective film. The film structure includes an adhesive film, a film stack, and a protective film. The adhesive film is deposited onto the substrate. The film stack is deposited onto the adhesive film alternating dielectric films and metal films. The metal films are non-continuous with a total thickness of the metal films at a predetermined value. The protective film is deposited onto an upper film of the film stack.

Abstract: A circuit board assembly includes a circuit board having an outer surface that is configured with a plurality of discrete electrical components that are each manufactured independently of one another. The circuit board assembly further includes a first protective dielectric layer overlying the outer surface, and a second dielectric layer overlying the first protective dielectric layer and the discrete electrical components. The second dielectric layer includes a dielectric material having modulus of elasticity less than 3.5 Giga-Pascal (GPa), a dielectric constant less than 3.0, a dielectric loss less than 0.008, a moisture absorption less than 0.04 percent, a breakdown voltage strength in excess of 2 million volts/centimeter (MV/cm), a temperature stability to 300° Celsius, pinhole free in films greater than 50 Angstroms, hydrophobic with a wetting angle greater than 45 degrees, capable of being deposited conformally over and under 3D structures with thickness uniformity less than or equal to 30%.

Abstract: A flight recorder includes an information input device, heat sensitive memory device electrically connected to the information input device, and housing enclosing the heat sensitive memory device. The housing is made with a first material and having a plurality of openings made through the housing. A sacrificial material is disposed between the housing and heat sensitive memory device. The sacrificial material having a lower melting temperature than the first material such that the sacrificial material changes state and egresses through the openings in the housing when exposed to heat to create an air gap between the housing and heat sensitive memory device. The first material includes nickel and the sacrificial material includes aluminum. A heat insulating layer is disposed between the sacrificial material and heat sensitive memory device. A second sacrificial material is disposed between the heat insulating layer and heat sensitive memory device.

Abstract: A module for packaging electronic components includes a carrier, at least one electronic component and a cap. The carrier has a first region and a second region. The electronic component is disposed on the first region of the carrier. The cap is mounted on the second region, and includes an inner layer and an outer layer, wherein the inner layer is made of a non-conductive material, the outer layer is made of a conductive material, and the inner layer made of the non-conductive material covers the electronic components and the whole first region.

Abstract: A resin-coated aluminum alloy sheet material for an aluminum electrolytic capacitor case has a superior formability even when being formed into an aluminum electrolytic capacitor case having a large height/diameter ratio, using a volatile press oil. A resin layer contains wax composed of at least one of polyethylene wax and carnauba wax, and has a thickness falling within a range from at least 2 ?m to at most 22 ?m. A total of lengths of wax particles, defined when the wax particles are cut along a straight line of 100 ?m optionally drawn on the surface of the resin layer, is at least 10 ?m. A number of the wax particles, featured by a cross-sectional shape having a size of at most 80% of the thickness of the resin layer and of at least 0.1 ?m, is from at least 3 to at most 50. A number of the wax particles, featured by a cross-sectional shape featured by a major axis extent having a size of more than 80% of the thickness of the resin layer is less than 10.

Abstract: This invention relates to flexible, transparent and conductive coatings and films formed using carbon nanotubes (CNT) and, in particular, single wall CNT, with polymer binders. Preferably, coatings and films are formed from CNT applied to transparent substrates forming one or multiple conductive layers at nanometer level of thickness. Polymer binders are applied to the CNT network coating having an open structure to provide protection through infiltration, and may comprise a basecoat, a topcoat, or a combination thereof, providing enhanced optical transparency, conductivity, moisture resistance, thermal resistance, abrasion resistance and interfacial adhesion. Polymers may be thermoplastics, thermosets, insulative, conductive or a combination thereof. A fluoropolymer containing binder is applied onto a CNT-based transparent conductive coating at nanometer level of thickness on a clear substrate. The fluoropolymers or blend can be either semi-crystalline or amorphous.

Abstract: A circuit board assembly includes an electrical component mounted on or in the assembly; a conductive layer, which is electrically connected to the electrical component; a high-temperature dissipation resin, which is of insulating material and is arranged so as to dissipate heat generated in the assembly; and a molding resin surrounding the electrical component. Heat, generated at electrical components in a circuit board assembly, is transferred and dispersed through the high-temperature dissipation material all over the assembly. Further, since the high-temperature dissipation resin is of an insulating material, it is unnecessary to consider a short-circuit problem in the assembly.

Abstract: Embodiments of the present invention provide a flexible circuit at least partially encapsulated by a cover layer. The flexible circuit includes a substrate having one or more openings. One or more electrical conductors are bonded to the top surface of the substrate. A first cover layer is bonded to the top surface of the substrate and to the electrical conductors. A second cover layer is bonded to the bottom surface of the substrate and to the first cover layer through the openings.

Abstract: A corrosion protection covering method for spliced regions of reinforcing steel is disclosed. The covering may include an outer, heat shrinkable layer and a flowable inner layer. The covering is applied to the spliced region, and then heated, causing the outer layer to constrict and thereby seal the taped area. The heat also causes the inner layer to liquify and fill any voids.