A semiconductor package includes a first base plate, first semiconductor structure, second base plate and filling layer. The first base plate has a first surface including first and second signal transmission regions. The first semiconductor structure located on the first surface is electrically connected to the first signal transmission region. The second base plate located on the first base plate includes a base and a first interconnection surface. The first interconnection surface is away from the first surface. The first interconnection surface has first and second interconnection regions communicated with each other. The first interconnection region is electrically connected to the second signal transmission region. The filling layer seals the first semiconductor structure, second base plate and first surface. The first interconnection region is not sealed, and the second interconnection region is. There is a preset height between a top surface of the filling layer and the first interconnection region.

A semiconductor package includes a substrate including an upper pad at a top surface of the substrate, a semiconductor chip on the substrate and including a chip pad at a top surface of the semiconductor chip, a connecting structure on the semiconductor chip and including a connecting pad at a top surface of the connecting structure and electrically connected to the upper pad, an encapsulant covering the substrate, the semiconductor chip, and the connecting structure, and a test terminal on the connecting structure and extending through the encapsulant. The connecting structure electrically interconnects the semiconductor chip and the test terminal.

Multiple component package structures are described in which an interposer chiplet is integrated to provide fine routing between components. In an embodiment, the interposer chiplet and a plurality of conductive vias are encapsulated in an encapsulation layer. A first plurality of terminals of the first and second components may be in electrical connection with the plurality of conductive pillars and a second plurality of terminals of first and second components may be in electrical connection with the interposer chiplet.

An electronic package is provided, in which an electronic element is disposed on an upper side of a circuit structure, a package layer covers the electronic element, and an action structure is embedded in the package layer, so that the action structure is exposed from a surface of the package layer, and then a bonding element is disposed on a lower side of the circuit structure and corresponding to the position of the action structure, so as to form a thermal conduction between the bonding element and the action structure. Therefore, a laser can transfer heat energy to the bonding element via the action structure, so that a solder material on the bonding element can be reflowed.

Some embodiments relate to a package. The package includes a first substrate, a second substrate, and an interposer frame between the first and second substrates. The first substrate has a first connection pad disposed on a first face thereof, and the second substrate has a second connection pad disposed on a second face thereof. The interposer frame is arranged between the first and second faces and generally separates the first substrate from the second substrate. The interposer frame includes a plurality of through substrate holes (TSHs) which pass entirely through the interposer frame. A TSH is aligned with the first and second connection pads, and solder extends through the TSH to electrically connect the first connection pad to the second connection pad.

An antenna module includes a ground layer including a through-hole; a feed via disposed to pass through the through-hole; a patch antenna pattern spaced apart from the ground layer and electrically connected to one end of the feed via; a coupling patch pattern spaced apart from the patch antenna pattern; a first dielectric layer to accommodate the patch antenna pattern and the coupling patch pattern; a second dielectric layer to accommodate at least a portion of the feed via and the ground layer; and electrical connection structures disposed between the first dielectric layer and the second dielectric layer to separate the first dielectric layer from the second dielectric layer.

A semiconductor package is provided, including a package component and a number of conductive features. The package component has a non-planar surface. The conductive features are formed on the non-planar surface of the package component. The conductive features include a first conductive feature and a second conductive feature respectively arranged in a first position and a second position of the non-planar surface. The height of the first position is less than the height of the second position, and the size of the first conductive feature is smaller than the size of the second conductive feature.

A semiconductor package includes an interposer including first and second surfaces opposite to each other. The semiconductor package also includes a heat dissipation layer disposed on the first surface of the interposer and a first semiconductor die mounted on the first surface of the interposer. The semiconductor package additionally includes a stack of second semiconductor dies mounted on the second surface of the interposer. The semiconductor package further includes a thermally conductive connection part for transferring heat from the stack of the second semiconductor dies to the heat dissipation layer.

A method of fabrication a package and a stencil structure are provided. The stencil structure includes a first carrier having a groove and stencil units placed in the groove of the first carrier. At least one of the stencil units is slidably disposed along sidewalls of another stencil unit. Each of the stencil units has openings.

A semiconductor package is provided. The semiconductor package includes: semiconductor dies, separated from one another, and including die I/Os at their active sides; and a redistribution structure, disposed at the active sides of the semiconductor dies and connected to the die I/Os, wherein the redistribution structure includes first and second routing layers sequentially arranged along a direction away from the die I/Os, the first routing layer includes a ground plane and first signal lines laterally surrounded by and isolated from the first ground plane, the first signal lines connect to the die I/Os and rout the die I/Os from a central region to a peripheral region of the redistribution structure, the second routing layer includes second signal lines and ground lines, and the second signal lines and the ground lines respectively extend from a location in the peripheral region to another location in the peripheral region through the central region.