A method for manufacturing a light emitting device includes: preparing a first substrate having an upper surface comprising an element placement region; placing a light emitting element in the element placement region; disposing an uncured, sheet-like light-transmissive member on the light emitting element and bringing an outer edge of a lower surface of the light-transmissive member into contact with an outer upper surface of the element placement region of the first substrate by pressing the light-transmissive member; and disposing a first protrusion portion along an outer edge of an upper surface of the light-transmissive member so that the first protrusion portion extends over the upper surface of the first substrate and the upper surface of the light-transmissive member.

In some examples, a semiconductor package comprises a semiconductor die; a conductive member coupled to the semiconductor die; and a wirebonded protrusion coupled to the conductive member. A physical structure of the wirebonded protrusion is determined at least in part by a sequence of movements of a wirebonding capillary used to form the wirebonded protrusion, the wirebonded protrusion including a ball bond and a bond wire, and the bond wire having a proximal end coupled to the ball bond. The bond wire has a distal end. The package also comprises a mold compound covering the semiconductor die, the conductive member, and the wirebonded protrusion. The distal end is in a common vertical plane with the ball bond and is not connected to a structure other than the mold compound.

In some examples, a semiconductor package comprises a semiconductor die; a conductive member coupled to the semiconductor die; and a wirebonded protrusion coupled to the conductive member. A physical structure of the wirebonded protrusion is determined at least in part by a sequence of movements of a wirebonding capillary used to form the wirebonded protrusion, the wirebonded protrusion including a ball bond and a bond wire, and the bond wire having a proximal end coupled to the ball bond. The bond wire has a distal end. The package also comprises a mold compound covering the semiconductor die, the conductive member, and the wirebonded protrusion. The distal end is in a common vertical plane with the ball bond and is not connected to a structure other than the mold compound.

A semiconductor device includes a semiconductor chip and a package. The semiconductor chip includes a signal processing circuit, a plurality of pads, and a first resistor which arc formed on a semiconductor substrate. On the semiconductor chip, there is no shot-circuiting between a first pad and a second pad of the plurality of pads. A signal input terminal of the signal processing circuit is connected to the second pad. The first resistor is provided between a reference potential supply terminal for supplying a power supply potential and the first pad. A specific terminal of the plurality of terminals of the package is connected to the first pad by a first bonding wire, and is connected to the second pad by a second bonding wire.

A semiconductor device includes a semiconductor chip and a package. The semiconductor chip includes a signal processing circuit, a plurality of pads, and a first resistor which arc formed on a semiconductor substrate. On the semiconductor chip, there is no shot-circuiting between a first pad and a second pad of the plurality of pads. A signal input terminal of the signal processing circuit is connected to the second pad. The first resistor is provided between a reference potential supply terminal for supplying a power supply potential and the first pad. A specific terminal of the plurality of terminals of the package is connected to the first pad by a first bonding wire, and is connected to the second pad by a second bonding wire.

Apparatuses relating generally to a microelectronic package having protection from interference are disclosed. In an apparatus thereof, a substrate has an upper surface and a lower surface opposite the upper surface and has a ground plane. A first microelectronic device is coupled to the upper surface of the substrate. Wire bond wires are coupled to the ground plane for conducting the interference thereto and extending away from the upper surface of the substrate. A first portion of the wire bond wires is positioned to provide a shielding region for the first microelectronic device with respect to the interference. A second portion of the wire bond wires is not positioned to provide the shielding region. A second microelectronic device is coupled to the substrate and located outside of the shielding region. A conductive surface is over the first portion of the wire bond wires for covering the shielding region.

Apparatuses relating generally to a microelectronic package having protection from interference are disclosed. In an apparatus thereof, a substrate has an upper surface and a lower surface opposite the upper surface and has a ground plane. A first microelectronic device is coupled to the upper surface of the substrate. Wire bond wires are coupled to the ground plane for conducting the interference thereto and extending away from the upper surface of the substrate. A first portion of the wire bond wires is positioned to provide a shielding region for the first microelectronic device with respect to the interference. A second portion of the wire bond wires is not positioned to provide the shielding region. A second microelectronic device is coupled to the substrate and located outside of the shielding region. A conductive surface is over the first portion of the wire bond wires for covering the shielding region.

The present application describes a system in package which features no printed circuit board inside an encapsulation structure and comprises: a copper holder with a silicon layer at a top face; a plurality of dies mounted on the silicon layer and electrically connected to a plurality of data pins of the copper holder; a passive element mounted on the silicon layer and electrically connected to the dies wherein the dies are electrically connected to the ground pin of the copper holder; a molding compound encasing the dies and the passive element on the top face of the copper holder.

The present application describes a system in package which features no printed circuit board inside an encapsulation structure and comprises: a copper holder with a silicon layer at a top face; a plurality of dies mounted on the silicon layer and electrically connected to a plurality of data pins of the copper holder; a passive element mounted on the silicon layer and electrically connected to the dies wherein the dies are electrically connected to the ground pin of the copper holder; a molding compound encasing the dies and the passive element on the top face of the copper holder.

A semiconductor package including: a redistribution layer including redistribution line patterns, redistribution vias connected to the redistribution line patterns, and a redistribution insulating layer surrounding the redistribution line patterns and the redistribution vias; semiconductor chips including at least one upper semiconductor chip disposed on a lowermost semiconductor chip of the semiconductor chips, wherein the at least one upper semiconductor chip is thicker than the lowermost semiconductor chip; bonding wires each having a first end and a second end, wherein the bonding wires connect the semiconductor chips to the redistribution layer, wherein the first end of each of the bonding wires is connected to a respective chip pad of the semiconductor chips and the second end of each of the bonding wires is connected to a respective one of the redistribution line patterns; and a molding member surrounding, on the redistribution layer, the semiconductor chips and the bonding wires.