A package includes a semiconductor die forming a power field effect transistor (FET), a control die, and a first leadframe. The control die is arranged on a first surface of the first leadframe, and the semiconductor die is arranged on an opposing second surface of the first leadframe. The package further includes a second leadframe including a first surface and a second surface opposing the first surface, wherein the semiconductor die is arranged on the first surface of the second leadframe to facilitate heat transfer therethrough. The package also includes mold compound at least partially covering the semiconductor die, the control die, the first leadframe and the second leadframe with the second surface of the second leadframe exposed.

A semiconductor device includes a semiconductor chip having a passivation film, a stress relieving layer provided on the passivation film, and a groove formed in a periphery of a surface of the semiconductor chip, the groove being provided inside of an edge of the semiconductor chip, wherein the stress relieving layer is partly disposed in the groove.

A semiconductor package includes a conductive pad, a semiconductor die with an aluminum bond pad over a dielectric layer of the semiconductor die, a gold bump on the aluminum bond pad, a first intermetallic layer of gold and aluminum between the aluminum bond pad and the gold bump, a copper ball bond on the gold bump, a second intermetallic layer of copper and gold between the copper ball bond and the gold bump, a copper wire extending from the copper ball bond to the conductive pad, a stitch bond between the copper wire and the conductive pad.

A method for forming a semiconductor package is disclosed herein. The method includes forming a package substrate having a first major surface and a second major surface opposite to the first major surface. The package substrate includes a recess region below the first major surface defined with a die region and a non-die region surrounding the die region. A semiconductor die is disposed in the die region within the recess region. A dam structure is disposed within the recess region. The dam structure surrounds the semiconductor die and extends upwardly to a height below the first major surface of the package substrate. The method also includes dispensing a liquid encapsulant material into the recess region. The liquid encapsulant material is surrounded by the dam structure and extends upwardly to a height below the height of the dam structure. A package lid is attached to the package substrate.

According to one embodiment, a semiconductor device includes a wiring board having a first surface. A first element is disposed on the first surface of the wiring board. A first resin layer covers the first element. A second element is larger than the first element and disposed on the first resin layer. The second element is superposed above the first element. A reinforcement member is disposed at a peripheral portion of the first resin layer and includes an edge disposed inside of the first resin layer. The reinforcement member has an upper surface above the first surface of the wiring board. The reinforcement member has a coefficient of linear expansion lower than the first resin layer. An encapsulating resin material, over the first surface of the wiring board, covers the first element, the second element, the first resin layer, and the reinforcement member.

Multi-chip modules may include stacked semiconductor devices having spacers therebetween. Discrete conductive elements may extend over the active surface of an underlying semiconductor device from respective bond pads of the underlying semiconductor device, through a space formed by the spacers, to respective contact areas on a substrate. Each discrete conductive element extending through two side openings opposite one another may extend from a respective centrally located bond pad proximate to a central portion of the active surface of the underlying semiconductor device. Each discrete conductive element extending through another, perpendicular opening may extend from a respective peripheral bond pad located proximate to a peripheral portion of the active surface of the underlying semiconductor device.

A semiconductor device includes a semiconductor chip having a passivation film, a stress relieving layer provided on the passivation film, and a groove formed in a periphery of a surface of the semiconductor chip, the groove being provided inside of an edge of the semiconductor chip, wherein the stress relieving layer is partly disposed in the groove.

A light-emitting element package according to an embodiment comprises: a body comprising a cavity; the cavity; a first frame and a second frame arranged on the bottom surface of the cavity; a first metal layer disposed on the first frame; an ultraviolet light-emitting element disposed on the first metal layer; and a second metal layer disposed on the second frame and electrically connected to the second frame, wherein the body comprises a separation portion between the first frame and the second frame, the second metal layer extends over the sloping surface of the cavity and the separation portion of the body, and the second metal layer is spaced apart from the first metal layer in the cavity and surrounds the first metal layer.

Techniques are disclosed for forming a frame on the backplane comprising structures at least partially circumscribing or enclosing metal contacts on the backplane. In some embodiments, the frame may comprise a photoresist. The dimensions and structural integrity of the frame can help prevent misalignment and/or damage of physical obtrusions of light-emitting structures during a bonding process of the light-emitting structures to the backplane.

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.