An apparatus including a circuit structure including a device stratum; one or more electrically conductive interconnect levels on a first side of the device stratum and coupled to ones of the transistor devices; and a substrate including an electrically conductive through silicon via coupled to the one or more electrically conductive interconnect levels so that the one or more interconnect levels are between the through silicon via and the device stratum. A method including forming a plurality of transistor devices on a substrate, the plurality of transistor devices defining a device stratum; forming one or more interconnect levels on a first side of the device stratum; removing a portion of the substrate; and coupling a through silicon via to the one or more interconnect levels such that the one or more interconnect levels is disposed between the device stratum and the through silicon via.

An example ceramic panel has a first surface and a second surface. The ceramic panel has a bond finger well on the first surface of the ceramic panel a scribe line well on the second surface of the ceramic panel. The ceramic panel also has a scribe line along the scribe line well.

A substrate has a first surface and a second surface opposite to the first surface. The substrate has at least one first recess on the first surface and a second recess on the second surface. The substrate includes electrode pads. The electrode pads are in the at least one first recess. The substrate has the at least one first recess located separate from the second recess in a plan view.

A package substrate may include first conductive patterns, a first insulation layer and a second insulation layer. The first conductive patterns may be electrically connected with a semiconductor chip. The first insulation layer may be on an upper surface and side surfaces of each of the first conductive patterns. The first insulation layer may include at least one opening under at least one of side surfaces of the semiconductor chip. The second insulation layer may be on a lower surface of each of the first conductive patterns. Thus, a gas generated from the DAF may be readily discharged through the opening. A spreading of a crack, which may be generated at the interface between the side surface of the semiconductor chip and the molding member, toward the conductive patterns of the package substrate may be limited and/or suppressed. Adhesion between the semiconductor chip and the molding member may be reinforced.

Semiconductor devices, and more particularly arrangements of fluorinated polymers with low dielectric loss for environmental protection in semiconductor devices are disclosed. Arrangements include conformal coatings or layers of fluorinated polymers that cover a semiconductor die on a package substrate of a semiconductor device. Such fluorinated polymer arrangements may also conformally coat various electrical connections for the semiconductor die, including wire bonds. Fluorinated polymers with low dielectric constants and low moisture permeability may thereby provide reduced moisture ingress in semiconductor devices while also reducing the impact of associated dielectric loss.

According to one embodiment, a semiconductor device includes a wiring board that has a first surface and a second surface opposed to the first surface, a semiconductor chip provided on the first surface, external connection terminals provided on the second surface, a sealing resin layer provided on the first surface, and a conductive shield layer that covers at least a portion of a side surface of the wiring board and the sealing resin layer. The wiring board includes a first ground wire that is electrically connected to the conductive shield layer, and a second ground wire that is electrically connected to the conductive shield layer and is electrically insulated from the first ground wire.

Embodiments of the invention include device packages and methods of forming such packages. In an embodiment, the method of forming a device package may comprise forming a reinforcement layer over a substrate. One or more openings may be formed through the reinforcement layer. In an embodiment, a device die may be placed into one of the openings. The device die may be bonded to the substrate by reflowing one or more solder bumps positioned between the device die and the substrate. Embodiments of the invention may include a molded reinforcement layer. Alternative embodiments include a reinforcement layer that is adhered to the surface of the substrate with an adhesive layer.

A unit includes a wiring board having a first face having a mounting portion on which an electronic device is mounted, a second face opposite to the first face, and end faces continuous with the first face and the second face, a resin member provided to cover the end faces and to have protrusions protruding upward from the end faces to face each other across a space above the mounting portion, and an insulating film covering the second face, wherein at least a part of an edge of the insulating film is provided away from an end of the second face on the end face side.

A semiconductor device includes a vertical column of wire bonds on substrate contact fingers of the device. Semiconductor dies are mounted on a substrate, and electrically coupled to the substrate such that groups of semiconductor dies may have bond wires extending to the same contact finger on the substrate. By bonding those wires to the contact finger in a vertical column, as opposed to separate, side-by-side wire bonds on the contact finger, an area of the contact finger may be reduced.

There is provided a semiconductor device including an insulating substrate provided with a circuit surface, and an external terminal bonded to the circuit surface. The circuit surface has an upper surface that is in contact with and bonded to a part of a lower surface of the external terminal. In at least a part of a portion where the upper surface of the circuit surface and the lower surface of the external terminal are in contact with each other, a melted portion of the circuit surface and the external terminal is formed. A gap between the upper surface of the circuit surface and the lower surface of the external terminal has a size of 20 μm or less. The circuit surface and the external terminal are each made of copper or copper alloy.