A semiconductor package structure and a method for manufacturing a semiconductor package structure are provided. The semiconductor package structure includes a carrier, a first encapsulant, and an interposer. The first encapsulant is on the carrier and defines a cavity. The interposer is disposed between the first encapsulant and the cavity. The first encapsulant covers a portion of the interposer.

A charging cable is related to the data transmission technology field, including: a data cable main body, a data connector and a power connector. The data cable main body includes: a wire sleeve and a signal and power line. The power connector includes a USB interface, a first circuit board and a first casing. The charging cable further includes: at least one LED lamp bead; at least one lampshade that is opaque, and a transparent optical fiber and a control switch for controlling the LED lamp bead.

A semiconductor device package includes a redistribution structure, a conductive substrate stacked on the redistribution structure and an encapsulant encapsulating the redistribution structure and the conductive substrate. The encapsulant encapsulates a side surface of the conductive substrate. A method for manufacturing an electronic device package includes: providing a carrier, forming a redistribution structure on the carrier, mounting a conductive substrate on a first surface of the redistribution structure, forming a first encapsulant to encapsulate the first surface of the redistribution structure and a side surface of the conductive substrate, and removing the carrier.

In some embodiments, the present invention is directed to an actuator which includes at least the following: a pre-stretched electro-active polymer film being pre-stretched in a single or biaxial planar directions; at least one first semi-stiff conductor attached to a first surface of the pre-stretched electro-active polymer film, wherein the first surface is parallel to the single or biaxial planar stretch directions; at least one second semi-stiff conductor attached to a second surface of the pre-stretched electro-active polymer film, wherein the second surface is opposite to the first surface; where the semi-stiff conductors are configured to: fix the pre-stretched electro-active polymer film in a pre-stretched state and allow the pre-stretched electro-active polymer film to expand; a pair of mechanical connectors coupled to each end of an active region of the pre-stretched electro-active polymer film.

An electronic device package structure including a substrate, a first circuit layer, a second circuit layer, an electronic device and an input/output device is provided. The first circuit layer includes a first conductive portion, a second conductive portion and a first curve portion located between the first conductive portion and the second conductive portion. At least a partial thickness of the first curve portion is greater than a thickness of the first conductive portion. The electronic device disposed on the second circuit layer is electrically connected to the second conductive portion of the first circuit layer. The input/output device disposed corresponding to the first conductive portion is electrically connected to the first conductive portion of the first circuit layer.

An apparatus is provided which comprises: a substrate, a die site on the substrate to couple with a die, a die side component site on the substrate to couple with a die side component, and a raised barrier on the substrate between the die and die side component sites to contain underfill material disposed at the die site, wherein the raised barrier comprises electroplated metal. Other embodiments are also disclosed and claimed.

In component mounting for mounting a pin connecting component having a pin on a board having a through-hole electrode, a solder paste is printed on the through-hole electrode through a screen mask having an opening corresponding to the through-hole electrode, a flux is transferred onto the pin by holding the pin connecting component and immersing the pin into a flux tank filled with the flux, and the pin onto which the flux is transferred is inserted into the through-hole electrode on which the solder paste is printed to mount the pin connecting component on the board.

A semiconductor package having an aperture in a die pad and solder in the aperture coplanar with a surface of the package is disclosed. The package includes a die pad, a plurality of leads, and a semiconductor die coupled to the die pad with a die attach material. A cavity or aperture is formed through the die pad to expose a portion of the die attach material. Multiple solder reflows are performed to reduce the presence of voids in the die attach material. In a first solder reflow, the voids of trapped gas that form when attaching the die to the die pad are released. Then, in a second solder reflow, solder is added to the aperture coplanar with a surface of the die pad. The additional solder can be the same material as the die attach material or a different material.

A connector assembly and a display device are provided. A connector assembly includes a first connector comprising a long-side portion at which a plurality of signal terminals is located and a short-side portion at which a power source voltage terminal is located, and a printed circuit board including a plurality of signal printed lines connected to the plurality of signal terminals and a power source voltage printed line connected to the power source voltage terminal, the first connector being arranged on the printed circuit board.

A capacitor loop substrate assembly may include a substrate with a loop shape, one or more capacitors or other electronic components on the substrate, and an opening in the substrate to allow the capacitor loop substrate assembly to be coupled to an integrated circuit package, such as a package including a die. Interconnects and/or contacts for interconnects may be formed in an integrated circuit package to couple the capacitor loop substrate assembly to the integrated circuit package.