A battery system has a battery cell including a can, and a ceramic substrate, including a patterned metallized surface, mounted to the can via a thermally conductive adhesive. The battery system also has a monolithic integrated circuit that measures and transmits data about the cell mounted to the patterned metallized surface such that the ceramic substrate and monolithic integrated circuit are electrically isolated from one another.

A method of manufacturing a packaged semiconductor device includes forming an assembly by placing a semiconductor die over a substrate with a die attach material between the semiconductor die and the substrate. A conformal structure which includes a pressure transmissive material contacts at least a portion of a top surface of the semiconductor die. A pressure is applied to the conformal structure and in turn, the pressure is transmitted to the top surface of the semiconductor die by the pressure transmissive material. While the pressure is applied, concurrently encapsulating the assembly with a molding compound and exposing the assembly to a temperature that is sufficient to cause the die attach material to sinter.

A package structure includes a semiconductor device and an adhesive pattern. The adhesive pattern surrounds the semiconductor device, wherein an angle θ is formed between a sidewall of the semiconductor device and a sidewall of the adhesive pattern, 0°<θ<90° wherein the adhesive layer has a first opening misaligned with a corner of the semiconductor device closest to the first opening.

A thermal interface material may be formed comprising a polymer material and a self-healing constituent. The thermal interface material may be used in an integrated circuit assembly between at least one integrated and a heat dissipation device, wherein the self-healing constituent changes the physical properties of the thermal interface material in response to thermo-mechanical stresses to prevent failure modes from occurring during the operation of the integrated circuit assembly.

A thermal interface material may be formed comprising a polymer material and a self-healing constituent. The thermal interface material may be used in an integrated circuit assembly between at least one integrated and a heat dissipation device, wherein the self-healing constituent changes the physical properties of the thermal interface material in response to thermo-mechanical stresses to prevent failure modes from occurring during the operation of the integrated circuit assembly.

A micro light emitting diode (LED) transfer device includes a transfer part configured to transfer a relay substrate having at least one micro LED; a mask having openings corresponding to a position of the at least one micro LED; a first laser configured to irradiate a first laser light having a first wavelength to the mask; a second laser configured to irradiate a second laser light having a second wavelength different from the first wavelength to the mask; and a processor configured to: control the at least one micro LED to contact a coupling layer of a target substrate, and based on the coupling layer contacting the at least one micro LED, control the first laser to irradiate the first laser light toward the at least one micro LED, and subsequently control the second laser to irradiate the second laser light toward the at least one micro LED.

A micro light emitting diode (LED) transfer device includes a transfer part configured to transfer a relay substrate having at least one micro LED; a mask having openings corresponding to a position of the at least one micro LED; a first laser configured to irradiate a first laser light having a first wavelength to the mask; a second laser configured to irradiate a second laser light having a second wavelength different from the first wavelength to the mask; and a processor configured to: control the at least one micro LED to contact a coupling layer of a target substrate, and based on the coupling layer contacting the at least one micro LED, control the first laser to irradiate the first laser light toward the at least one micro LED, and subsequently control the second laser to irradiate the second laser light toward the at least one micro LED.

Disclosed is an LED assembly having an omnidirectional light field. The LED assembly has a transparent substrate with first and second surfaces facing to opposite orientations respectively. LED chips are mounted on the first surface and are electrically interconnected by a circuit. A transparent capsule with a phosphor dispersed therein is formed on the first surface and substantially encloses the circuit and the LED chips. First and second electrode plates are formed on the first or second surface, and electrically connected to the LED chips.

Embodiments for a packaged semiconductor device and methods of making are provided herein, where a packaged semiconductor device includes a package body having a recess in which a pressure sensor is exposed; a polymeric gel within the recess that vertically and laterally surrounds the pressure sensor; and a protection layer including a plurality of beads embedded within a top region of the polymeric gel.

A heat dissipation structure is provided and includes a heat dissipation body and an adjustment channel. A carrying area and an active area adjacent to the carrying area are defined on a surface of the heat dissipation body, the carrying area is used for applying a first heat dissipation material thereonto, and the adjustment channel is formed in the active area, where one end of the adjustment channel communicates with the outside of the heat dissipation structure, and the other end communicates with the carrying area. Therefore, when the heat dissipation body is coupled to the electronic component by the first heat dissipation material, the adjustment channel can adjust a volume of the first heat dissipation material.