The present disclosure provides an electronic package. The electronic package includes a substrate, a first component disposed on the substrate and configured to detect an external signal, and an encapsulant disposed on the substrate. The electronic package also includes a protection element disposed on the substrate and physically separating the first device from the encapsulant and exposing the first device. The present disclosure also provides an electronic device.

A semiconductor package includes a semiconductor die, a first thermal conductive pattern and a second thermal conductive pattern. The semiconductor die is encapsulated by an encapsulant. The first thermal conductive pattern is disposed aside the semiconductor die in the encapsulant. The second thermal conductive pattern is disposed over the semiconductor die, wherein the first thermal conductive pattern is thermally coupled to the semiconductor die through the second thermal conductive pattern and electrically insulated from the semiconductor die.

A power module includes a plurality of conductive wire groups and a sealing member. The plurality of conductive wire groups each include a first bonded portion and a second bonded portion. A maximum gap between intermediate portions of a pair of conductive wire groups adjacent to each other is larger than a first gap between the first bonded portions of the pair of conductive wire groups adjacent to each other. The maximum gap between the intermediate portions of the pair of conductive wire groups adjacent to each other is larger than a second gap between the second bonded portions of the pair of conductive wire groups adjacent to each other. Therefore, the power module is improved in reliability.

A method for providing electromagnetic shielding of a semiconductor die includes attaching a semiconductor die to a package substrate of a packaged radio frequency module, where the package substrate includes one or more radio frequency circuits fabricated therein. The method also includes encapsulating the semiconductor die with a molding compound. The method also includes at least partially covering the molding compound with an electromagnetic shielding structure having an outer layer including cobalt. A phone board assembly can include the packaged radio frequency module attached to a printed circuit board. The packaged radio frequency module can be incorporated into a mobile device.

Wafer-level packaging structure is provided. First chips are bonded to the device wafer. A first encapsulation layer is formed on the device wafer, covering the first chips. The first chip includes: a chip front surface with a formed first pad, facing the device wafer; and a chip back surface opposite to the chip front surface. A first opening is formed in the first encapsulation layer to expose at least one first chip having an exposed chip back surface for receiving a loading signal. A metal layer structure is formed covering the at least one first chip, a bottom and sidewalls of the first opening, and the first encapsulation layer, followed by an alloying treatment on the chip back surface and the metal layer structure to form a back metal layer on the chip back surface.

A package includes an integrated circuit. The integrated circuit includes a first chip, a second chip, a third chip, and a fourth chip. The second chip and the third chip are disposed side by side on the first chip. The second chip and the third chip are hybrid bonded to the first chip. The fourth chip is fusion bonded to at least one of the second chip and the third chip.

According to one embodiment, a semiconductor memory system includes a substrate, a plurality of elements and an adhesive portion. The substrate has a multilayer structure in which wiring patterns are formed, and has a substantially rectangle shape in a planar view. The elements are provided and arranged along the long-side direction of a surface layer side of the substrate. The adhesive portion is filled in a gap between the elements and in a gap between the elements and the substrate, where surfaces of the elements are exposed.

Structures and formation methods of a chip package are provided. The chip package includes a semiconductor die having a conductive element and an antenna element over the semiconductor die. The chip package also includes a first conductive feature electrically connecting the conductive element of the semiconductor die and the antenna element. The chip package further includes a protective layer surrounding the first conductive feature. In addition, the chip package includes a second conductive feature over the first conductive feature. A portion of the second conductive feature is between the first conductive feature and the protective layer.

A semiconductor package includes a supporting wiring structure including a first redistribution dielectric layer and a first redistribution conductive structure; a frame on the supporting wiring structure, having a mounting space and a through hole, and including a conductive material; a semiconductor chip in the mounting space and electrically connected to the first redistribution conductive structure; a cover wiring structure on the frame and the semiconductor chip and including a second redistribution dielectric layer and a second redistribution conductive structure; an antenna structure on the cover wiring structure; a connection structure extending in the through hole and electrically connecting the first redistribution conductive structure to the second redistribution conductive structure; and a dielectric filling member between the connection structure in the through hole and the frame and surrounding the semiconductor chip, the frame, and the connection structure.

A semiconductor packaging structure includes a die including a bond pad and a first metal layer structure disposed on the die, the first metal layer structure having a first width, the first metal layer structure including a first metal layer, the first metal layer electrically coupled to the bond pad. The semiconductor packaging structure also includes a first photosensitive material around sides of the first metal layer structure and a second metal layer structure disposed over the first metal layer structure and over a portion of the first photosensitive material, the second metal layer structure electrically coupled to the first metal layer structure, the second metal layer structure having a second width, where the second width is greater than the first width. Additionally, the semiconductor packaging structure includes a second photosensitive material around sides of the second metal layer structure.