Packaged devices and methods of manufacturing the devices are described herein. The packaged devices may be fabricated using heterogeneous devices and asymmetric dual-side molding on a multi-layered redistribution layer (RDL) structure. The packaged devices may be formed with a heterogeneous three-dimensional (3D) Fan-Out System-in-Package (SiP) structure having small profiles and can be formed using a single carrier substrate.

A semiconductor device can comprise a substrate dielectric structure and a substrate conductive structure that traverses the substrate dielectric structure and comprises first and second substrate terminals; an electronic component with a component terminal coupled to the first substrate terminal; and a first antenna element with a first element terminal coupled to the second substrate terminal, a first element head side adjacent a first antenna pattern, a first element base side opposite the first element side, and a first element sidewall. The first element terminal can be exposed from the first element dielectric structure at the first element base side or at the first element sidewall. The first antenna pattern can be coupled to the substrate through the first element terminal. The substrate conductive structure can couple the first antenna element to the electronic component. Other examples and methods are also disclosed.

Disclosed is a microelectronic device assembly comprising a substrate having conductors exposed on a surface thereof. Two or more stacks of microelectronic devices are located on the substrate, and microelectronic devices of the stacks are connected to vertical conductive paths external to the stacks and extending to the substrate and to lateral conductive paths extending between the stacks. Methods of fabrication are also disclosed.

A semiconductor device can comprise a substrate dielectric structure and a substrate conductive structure that traverses the substrate dielectric structure and comprises first and second substrate terminals; an electronic component with a component terminal coupled to the first substrate terminal; and a first antenna element with a first element terminal coupled to the second substrate terminal, a first element head side adjacent a first antenna pattern, a first element base side opposite the first element side, and a first element sidewall. The first element terminal can be exposed from the first element dielectric structure at the first element base side or at the first element sidewall. The first antenna pattern can be coupled to the substrate through the first element terminal. The substrate conductive structure can couple the first antenna element to the electronic component. Other examples and methods are also disclosed.

Disclosed is a method for producing an electronic component, the method including: disposing a plurality of electronic components on an adhesive layer of a composite substrate including a support, a temporary fixing material layer, and the adhesive layer with a connection part in contact with the adhesive layer interposed between the adhesive layer and the electronic components; fixing the plurality of electronic components to the composite substrate by curing the adhesive layer; forming a sealing layer sealing the electronic components; obtaining a sealed structure by peeling off the temporary fixing material layer from the adhesive layer; and a forming a circuit surface by grinding the sealed structure from the adhesive layer side. The plurality of electronic components include an IC chip and a chip-type passive component. The passive component is disposed on the adhesive layer by a method including in the following order: disposing a conductor precursor for pattern formation as the connection part on the adhesive layer; placing the passive component on the conductor precursor; and forming a conductive pattern as the connection part by heating the conductor precursor.

A method comprises applying a metal-paste printing process to a surface-mount device to form a metal pillar, placing a first semiconductor die adjacent to the surface-mount device, forming a molding compound layer over the first semiconductor die and the surface-mount device, grinding the molding compound layer until a top surface of the first semiconductor die is exposed and forming a plurality of interconnect structures over the molding compound layer.

A method of making a semiconductor device, includes: forming a first molding layer on a substrate; forming a first plurality of vias in the first molding layer; forming a first conductive line over the first molding layer, wherein the first conductive line is laterally disposed over the first molding layer and a first end of the conductive line aligns with and is electrically coupled to a first via of the first plurality of vias; forming a second molding layer above the first molding layer; and forming a second plurality of vias in the second molding layer, wherein a second via of the second plurality of vias aligns with and is electrically coupled to a second end of the conductive line, and wherein the second plurality of vias, the conductive line, and the first plurality of vias are electrically coupled to one another.

A semiconductor package including a core structure, in which a first and second semiconductor chips and passive components are embedded, a connection structure disposed on a first side of the core structure, and including a redistribution layer electrically connected to the first and second semiconductor chips and the passive components, and a metal pattern layer and a backside wiring layer disposed on a second side of the core structure opposing the first side, and spaced apart from each other. The core structure includes a first metal layer surrounding the first semiconductor chip, a second metal layer surrounding the first semiconductor chip, and the first metal layer, a third metal layer surrounding the second semiconductor chip, and a fourth metal layer surrounding the second semiconductor chip, the passive components, and the third metal layer, and each of the first to fourth metal layers is electrically connected to the metal pattern layer.

A package includes a first redistribution structure, a second redistribution structure, an inductor, a permalloy core, and a die. The second redistribution structure is over the first redistribution structure. The inductor includes a first portion, a second portion, and a third portion. The first portion is embedded in the first redistribution structure, the third portion is embedded in the second redistribution structure, and the second portion connects the first and third portions of the inductor. The permalloy core is located between the first and third portions of the inductor. The die is disposed adjacent to the second portion of the inductor.

When a specification setting unit sets a specification of a lot number “k+1” after setting a specification of a lot number “k”, a mounting program selector performs a mounting program corresponding to the lot number “k”, and then selects a mounting program corresponding to the lot number “k+1” according to matching between a mounting number from the mounting program and a planned number of products of the lot number “k”. A printing program selector selects a printing program corresponding to the lot number “k”, and then selects a printing program corresponding to the lot number “k+1” according to matching between a sum of a printing number from the printing program and a defective product number and the planned number of products of the lot number “k”. Consequently, on-demand production of an electronic device can easily be manufactured on a manufacturing line.