A semiconductor package is provided. The semiconductor package includes a first structure with a first insulating layer and a connection pad which penetrates through the first insulating layer; and a second structure with a second insulating layer bonded to the first insulating layer and a pad structure provided in a recess portion of the second insulating layer. The pad structure is bonded to and wider than the connection pad. The pad structure includes: an electrode pad disposed on a bottom surface of the recess portion; a solder disposed on the electrode pad and bonded to the connection pad; and a conductive support disposed to surround a side surface of the solder on the electrode pad and bonded to the first insulating layer. A melting point of the conductive support is higher than a melting point of the solder.

Disclosed are semiconductor packages and their fabrication methods. The semiconductor package comprises a first substrate having first pads on a first surface of the first substrate, a second substrate on the first substrate and having a plurality of second pads on a second surface of the second substrate, and connection terminals between the first substrate and the second substrate and correspondingly coupling the first pad to the second pads. Each of the connection terminals has a first major axis and a first minor axis that are parallel to the first surface of the first substrate and are orthogonal to each other. When viewed in a plan view, the first minor axis of each of the connection terminals is directed toward a center of the first substrate.

Without causing characteristic variations in paired elements, the increase in development cost and development period is suppressed. A plurality of MOS units 30 are arranged adjacent to each other on a main surface of a semiconductor substrate in a plan view, each of the plurality of MOS unit is comprised of at least one MOSFET and has same structure. Above the plurality of MOS units 30, a multilayer wiring layer is formed. In an uppermost wiring layer of the multilayer wiring layer, wiring M8 is formed. Each of the plurality of MOS units 3Q includes MOS unit 10 and MOS unit 20, which constitute a part of the differential circuit as paired elements. The coverage rate of MOS unit 10 covered by wiring M8 is the same as the coverage rate of MOS unit 20 covered by wiring M8 in the plan view.

A semiconductor device assembly is provided. The assembly includes a package substrate which has a tunneled interconnect structure. The tunneled interconnect structure has a solder-wettable surface, an interior cavity, and at least one microvia extending from the surface to the cavity. The assembly further includes a semiconductor device disposed over the substrate and a solder joint coupling the device and the substrate. The joint comprises the solder between the semiconductor device and the interconnect structure, which includes the solder on the surface, the solder in the microvia, and the solder within the interior cavity.

Disclosed herein is an electronic component that includes: a substrate; a capacitor on the substrate; a first insulating resin layer embedding therein the capacitor; an inductor provided on the first insulating resin layer and connected to the capacitor, the inductor including a conductor pattern; a second insulating resin layer embedding therein the inductor; a third insulating resin layer on the second insulating resin layer; a post conductor having a lower end and an upper end and penetrating the third insulating resin layer such that the lower end of the post conductor is connected to the inductor; and a terminal electrode on the third insulating resin layer and connected to the upper end of the post conductor. In a thickness direction of the substrate, the height of the post conductor is larger than a thickness of a conductor pattern constituting the inductor.

Methods of making a semiconductor device assembly are provided. The methods can comprise providing a first semiconductor device having a first dielectric material at a first surface, providing a carrier wafer having a second dielectric material at a second surface, and forming a dielectric-dielectric bond between the first dielectric material and the second dielectric material. At least one of the first surface and the second surface includes a cavity configured to entrap a gas during the formation of the bond. The method can further include stacking one or more second semiconductor devices over the first semiconductor device to form the semiconductor device assembly, and removing the semiconductor device assembly from the carrier wafer.

A semiconductor device includes a semiconductor element having a surface on which a first electrode and a second electrode are disposed, a conductor plate having a surface facing the surface of the semiconductor element and electrically connected to the first electrode, an insulating layer disposed on the surface of the conductor plate and covers a part of the surface of the conductor plate, and a conductor circuit pattern disposed on the insulating layer. The conductor circuit pattern has at least one conductor line electrically connected to the semiconductor element. The at least one conductor line includes a conductor line electrically connected to the second electrode.

A display device includes a substrate including a display area and a pad area; a first conductive layer including a first pad electrode in the pad area; and a second conductive layer the second conductive layer includes a second pad electrode on the first pad electrode in the pad area; the first pad electrode and the second pad electrode overlap in a first direction that is a thickness direction, and do not overlap in a second direction perpendicular to the first direction.

This insulation module is provided with: a first conductor and a second conductor, which are buried in an insulating layer so as to face each other at a distance in the thickness direction of the insulating layer; a first electrode which is connected to the first conductor; a second electrode which is connected to the second conductor, while being arranged at a position that is away from the first electrode when viewed from the thickness direction of the insulating layer; a passivation layer which is formed on the surface of the insulating layer; a low dielectric constant layer which is formed on the surface of the passivation layer, and has a lower dielectric constant than the passivation layer; and a mold resin which covers the low dielectric constant layer.

A reliability of a semiconductor device can be improved by measuring a value of a current flowing through a power transistor accurately. A semiconductor chip includes a power transistor and a source electrode electrically connected to a source region of the power transistor. The source electrode and a lead terminal are electrically connected to each other via a wire. The source electrode includes detection points for detecting the value of the current flowing through the power transistor. The detection points are arranged so as to sandwich a bonding point of the wire bonded to the source electrode.