A semiconductor device includes a substrate that includes an opening extending through a thickness of the substrate, a frame that includes an integrated circuit (IC) die pad in the opening and a plurality of arms extending outwardly from the IC die pad, an IC mounted on the IC die pad, a plurality of bonding elements electrically coupling the substrate with the IC without the frame being an intermediary coupling element, and an encapsulant surrounding the IC, the plurality of bonding elements, and the plurality of arms. The substrate has a first major surface and a second major surface. Each arm is devoid of a contact pad. Each arm has a distal end coupled to the first major surface of the substrate, and each arm has a proximal end disposed over the first major surface of the substrate.

An embodiment of the present invention provides an element transferring method that may increase a yield of transferring an element, and an electronic panel manufacturing method using the same. The element transferring method includes: preparing a carrier film in which a first surface of an element on which a terminal is formed is adhered to an adhesive surface; providing a cover adhesive layer on the adhesive surface so that the second surface of the element that is opposite to the first surface and where the terminal is not formed is covered; transferring the element to the target substrate by adhering the cover adhesive layer to the target substrate while the second surface is facing the target substrate; and separating the carrier film from the element, wherein in transferring the element, the carrier film is pressed so that the surface of the cover adhesive layer is flat at the same height as the terminal.

A semiconductor device is provided that includes a lead frame, a die attached to the lead frame using a first solder, a source clip and a gate clip attached to the die using a second solder, and a drain clip attached to the lead frame. The semiconductor device is inverted, so that the source clip and the gate clip are positioned on the bottom side of the semiconductor device, and the lead frame is positioned on the top side of the semiconductor device so that the lead frame is a top exposed drain clip.

A semiconductor device includes a multi-layer board which a wiring pattern and a grounding pattern are formed. A plurality of semiconductor elements are mounted on the multi-layer board. An insulating sealing member is provided on the multi-layer board and is covering the plurality of semiconductor elements. A metal film is provided on the insulating sealing member. An in-groove metal is provided in contact with a plurality of grooves extending from a side-surface upper end of the insulating sealing member to a side-surface lower end of the multi-layer board. An in-hole metal is provided in an inner wall of a hole penetrating through the insulating sealing member and is extending to the multi-layer board. The in-hole metal is contacting with the metal film and the grounding pattern.

The present disclosure relates to a radio frequency (RF) device that includes a mold device die and a multilayer redistribution structure underneath the mold device die. The mold device die includes a device region with a back-end-of-line (BEOL) portion and a front-end-of-line (FEOL) portion over the BEOL portion, and a first mold compound. The FEOL portion includes an active layer, a contact layer, and isolation sections. Herein, the active layer and the isolation sections reside over the contact layer, and the active layer is surrounded by the isolation sections. The first mold compound resides over the active layer without silicon crystal, which has no germanium content, in between. The multilayer redistribution structure includes redistribution interconnections and a number of bump structures that are at bottom of the multilayer redistribution structure and electrically coupled to the mold device die via the redistribution interconnections.

A method includes forming an interconnect component including a plurality of dielectric layers that include an organic dielectric material, and a plurality of redistribution lines extending into the plurality of dielectric layers. The method further includes bonding a first package component and a second package component to the interconnect component, encapsulating the first package component and the second package component in an encapsulant, and precutting the interconnect component using a blade to form a trench. The trench penetrates through the interconnect component, and partially extends into the encapsulant. The method further includes performing a singulation process to separate the first package component and the second package component into a first package and a second package, respectively.

Disclosed are wiring substrates, methods of fabricating the same, and methods of fabricating semiconductor packages. The wiring substrate includes a dielectric layer that includes a plurality of unit regions, a sawing region that surrounds each of the unit regions, and an edge region that surrounds the unit regions and the sawing region, a first upper protection pattern on a top surface of the dielectric layer on the unit regions and the sawing region, and a second upper protection pattern on a top surface of the dielectric layer on the edge region. The second upper protection pattern surrounds the first upper protection pattern when viewed in plan and includes a dielectric material different from a dielectric material of the first upper protection pattern.

A semiconductor device assembly includes a first remote distribution layer (RDL), the first RDL comprising a lower outermost planar surface of the semiconductor device assembly; a first semiconductor die directly coupled to an upper surface of the first RDL by a first plurality of interconnects; a second RDL, the second RDL comprising an upper outermost planar surface of the semiconductor device assembly opposite the lower outermost planar surface; a second semiconductor die directly coupled to a lower surface of the second RDL by a second plurality of interconnects; an encapsulant material disposed between the first RDL and the second RDL and at least partially encapsulating the first and second semiconductor dies; and a third plurality of interconnects extending fully between and directly coupling the upper surface of the first RDL and the lower surface of the second RDL.

The present disclosure provides a package device and a manufacturing method thereof. The package device includes an electronic device, a conductive pad having a first bottom surface, and a redistribution layer disposed between the conductive pad and the electronic device. The redistribution layer has a second bottom surface, and the conductive pad is electrically connected to the electronic device through the redistribution layer. The first bottom surface is closer to the electronic device than the second bottom in a normal direction of the electronic device.

A semiconductor structure includes a fan-out package, a packaging substrate, an solder material portions bonded to the fan-out package and the packaging substrate, an underfill material portion laterally surrounding the solder material portions, and at least one cushioning film located on the packaging substrate and contacting the underfill material portion and having a Young's modulus is lower than a Young's modulus of the underfill material portion.