A shielding film comprises multiple layers including one or more of a structured adhesive layer, an electrically conductive layer, an electrically insulative thermally conductive layer, and an electrically conductive adhesive layer. The electrically conductive shielding layer extends laterally beyond the structured adhesive layer. The electrically insulative thermally conductive layer is disposed between the electrically conductive shielding layer and the structured adhesive layer and is coextensive with the structured adhesive layer. The electrically conductive adhesive layer is disposed between the electrically conductive shielding layer and the thermally conductive layer and is coextensive with the electrically conductive shielding layer. When the multilayer shielding film is placed on an electronic device mounted on a circuit board and under application of one or more of heat, vacuum, and pressure, the multilayer shielding film conforms to the electronic device and the electrically conductive adhesive layer adheres to the circuit board providing a seal between the multilayer shielding film and the circuit board.

A polymer layering process that encapsulates and protects electronics components with complex and imprecise geometries. The protective layering process provides a combination of a flexible mold and/or a rigid mold that apply close-forming, encapsulating the polymer layers to the electronic components and precision assemblies. Polymer layer protective jackets are shaped to as-populated circuit boards and assemblies, providing tightly fit barriers with fine resolution accommodating imprecise geometries. The protective jackets can be formed in rigid, semi-rigid, or highly flexible polymer films, to protect the circuitry from the elements, CTE mismatches, shock and vibration loads and extreme g-forces, and external electromagnetic emissions. By altering the protect layer configuration, the protective layer can accommodate populated circuit board assembly with high heat generation component(s).

A component carrier includes a first level stack of first plural of electrically conductive layer structures and/or first electrically insulating layer structures; a first component aligned within a first through hole cut out in the first level stack such that one of an upper or a lower surface of the first component is substantially flush with an respective upper or a lower surface of the first level stack second electrically conductive layer structures and/or second electrically insulating layer structures attached onto the upper and the lower surface of the first level stack thereby covering the first component at the upper and the lower surface of the first component and pressed to form a second level stack. A second component is aligned within a second through hole cut out in the second level stack such that one of upper or a lower surface of the second component is substantially flush with an upper or a lower surface of the second level stack.

Multiple encapsulated LED arrays on a single printed circuit board of an LED engine, the LED engine including a plurality of LED arrays that are mounted on the printed circuit board in a spaced apart configuration, and are electrically isolated from each other, and a plurality of encapsulation layers, wherein each of the encapsulation layers is configured to encapsulate each of the LED arrays, and is further configured to protect the area proximal to the LED engine from arc or spark generated by the LED engine, wherein each of the encapsulation layers includes a plurality of blisters that are configured to encapsulate at least one LED of an LED array, and is further configured to transform the light emitted by the LEDs into a desired light beam pattern, and at least one planar portion configured to encapsulate electrical traces formed on the printed circuit board.

Systems and methods describe herein provide a solution to the technical problem of creating a wearable electronic devices. In particular, these systems and methods enable electrical and mechanical attachment of stretchable or flexible electronics to fabric. A stretchable or flexible electronic platform is bonded to fabric using a double-sided fabric adhesive, and conductive adhesive is used to join pads on the electronic platform to corresponding electrical leads on the fabric. An additional waterproofing material may be used over and beneath the electronic platform to provide a water-resistant or waterproof device This stretchable or flexible electronic platform integration process allows the platform to bend and move with the fabric while protecting the conductive connections. By using flexible and stretchable conductive leads and adhesives, the platform is more flexible and stretchable than traditional rigid electronics enclosures.

A method of manufacturing a System in Package (SiP) module includes: welding required electronic units by the SiP module onto a top surface of a Printed Circuit Board (PCB), with welding spots being reserved on a bottom surface of the PCB for obtaining a PCB assembly (PCBA) of the SiP module; pasting tightly a functional film on a surface of the electronic units of the PCBA; filling on plastic materials on the top surface of the PCBA, ensuring that the plastic materials covers the electronic units and the functional film on the top surface of the PCBA, and obtaining solidified PCBA after the plastic materials are solidified; and cutting the solidified PCBA for obtaining a plurality of the SiP modules.

An LED display device including: a bottom case, electronic components, a circuit board, and an LED lamp group, with no mask covering above the LED lamp group. A cured resin layer is potted over the LED lamp group fixed on the circuit board, and the cured resin layer is adhered with a light-transmitting film, and the cured resin layer and the light-transmitting film together serves as a protective layer. The LED display device has advantages in adjusting and controlling the contrast, viewing angle, and color uniformity of the display device; the performance in moisture proof, windproof, rainproof, anti-corrosion, heat dissipation, and ultraviolet resistance is obviously improved, which can significantly reduce the lamp dysfunction rate and lamp collision rate of the display device, prevent the lamp bead from falling off and avoid other damage to the lamp bead, thereby making the maintenance procedure simpler.

A wiring board may include a core portion having first and second surfaces, and first and second buildup portions on the first and second surfaces, respectively. Each of the first and second buildup portions may include a first insulating layer on the core portion, a wire pattern on the first insulating layer, a second insulating layer on the first insulating layer to cover the wire pattern, and a protection layer covering the second insulating layer and exposing a portion of the wire pattern. The second insulating layer may include a resin layer and inorganic fillers distributed in the resin layer. The fillers may not be provided in the protection layer, and the resin layer of the second insulating layer and the protection layer may be formed of the same material. The wire patterns of the first and second buildup portions may be electrically connected to each other.

Disclosed is an electromagnetic shielding structure of a solid state driver (SSD), and particularly an electromagnetic shielding structure of an SSD, in which an electromagnetic shielding structure of a closed shield can type is achieved based on an electromagnetic shielding structure that employs an electromagnetic shielding coating layer electrically connected to a ground via hole formed in a printed circuit board (PCB) and a lower electromagnetic shielding layer formed inside the PCB and electrically connected to the electromagnetic shielding coating layer through the ground via hole, thereby improving electromagnetic shielding performance.

Encapsulated conformal electronic devices, encapsulated conformal integrated circuit (IC) systems, and methods of making and using encapsulated conformal electronic devices are presented herein. A conformal IC device is disclosed which includes a flexible substrate, electronic circuitry attached to the flexible substrate, and a flexible multi-part encapsulation housing encasing therein the electronic circuitry and flexible substrate. The multi-part housing includes first and second encapsulation housing components. The first encapsulation housing component has recessed regions for seating therein the electronic circuitry, while the second encapsulation housing component has recessed regions for seating therein the flexible substrate. First encapsulation housing component optionally includes a recessed region for seating therein the flexible substrate. Either housing component may include one or more projections that pass through holes in the substrate to engage complementary depressions in the other housing component to thereby align and interlock the encapsulation housing components with the flexible substrate and electronic circuitry.