A semiconductor device according to embodiments includes a first base material having a first side surface, a first semiconductor chip provided above the first base material, a first insulating plate provided between the first base material and the first semiconductor chip, a first metal plate provided between the first insulating plate and the first semiconductor chip, a first bonding material provided between the first metal plate and the first semiconductor chip, the first bonding material bonding the first metal plate and the first semiconductor chip, a second bonding material provided between the first base material and the first insulating material, the second bonding material bonding the first base material and the first insulating plate, a second base material having a second side surface, a second semiconductor chip provided above the second base material, a second insulating plate provided between the second base material and the second semiconductor chip, a second metal plate provided between the second insulating plate and the second semiconductor chip, a third bonding material provided between the second metal plate and the second semiconductor chip, the third bonding material bonding the second metal plate and the second semiconductor chip, a fourth bonding material provided between the second base material and the second insulating plate, the fourth bonding material bonding the second base material and the second insulating plate, and a first base bonding portion provided between the second side surface and the first side surface and bonded to the first side surface and the second side surface.

A leadless packaged semiconductor device includes a metal substrate having at least a first through-hole aperture having a first outer ring and a plurality of cuts through the metal substrate to define spaced apart metal pads on at least two sides of the first through-hole aperture. A semiconductor die that has a back side metal (BSM) layer on its bottom side and a top side with circuitry coupled to bond pads is mounted top side up on the first outer ring. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the first through-hole aperture that provides a die attachment that fills a bottom portion of the first through-hole aperture. Bond wires are between metal pads and the bond pads. A mold compound is also provided including between adjacent ones of the metal pads.

A leadless packaged semiconductor device includes a metal substrate having at least a first through-hole aperture having a first outer ring and a plurality of cuts through the metal substrate to define spaced apart metal pads on at least two sides of the first through-hole aperture. A semiconductor die that has a back side metal (BSM) layer on its bottom side and a top side with circuitry coupled to bond pads is mounted top side up on the first outer ring. A metal die attach layer is directly between the BSM layer and walls of the metal substrate bounding the first through-hole aperture that provides a die attachment that fills a bottom portion of the first through-hole aperture. Bond wires are between metal pads and the bond pads. A mold compound is also provided including between adjacent ones of the metal pads.

A semiconductor device includes at least one member that is partially sealed by a sealing material and has a part of thereof being exposed from the sealing material, a reversible temperature indicating material, and an irreversible temperature indicating material. Each of the reversible temperature indicating material and the irreversible temperature indicating material is provided on a surface of any one of the at least one member.

A method including stacking a number of silicon dice such that one or more edges of the dice are in vertical alignment, where the one or more edges include a number of connection pads. The method also includes positioning a connecting wire on a substantially perpendicular axis to the one or more edges. The connecting wire includes a number of solder blocks formed thereon. The solder blocks are spaced at intervals associated with a distance between a first set of aligned connection pads on the dice. The connecting wire is positioned such that the solder blocks are in contact with the first set of aligned connection pads. The method also includes applying heat to cause the solder blocks to reflow and physically and electrically couple the connecting wire to the connection pads.

An apparatus includes an integrated circuit and a substrate coupled to the integrated circuit. The substrate includes a primary layer having a first surface that is a first external surface of the substrate. The primary layer includes an open area that extends through the primary layer to an inner layer of the substrate. The substrate includes a secondary layer. The inner layer is located between the primary layer and the secondary layer. The inner layer includes a third surface that is orientated approximately parallel to the first surface of the primary layer. A portion of the third surface of the inner layer is exposed via the open area of the primary layer. A first plurality of wire bond pads are disposed on the portion of the third surface of the inner layer that is exposed via the open area of primary layer.

An apparatus includes an integrated circuit and a substrate coupled to the integrated circuit. The substrate includes a primary layer having a first surface that is a first external surface of the substrate. The primary layer includes an open area that extends through the primary layer to an inner layer of the substrate. The substrate includes a secondary layer. The inner layer is located between the primary layer and the secondary layer. The inner layer includes a third surface that is orientated approximately parallel to the first surface of the primary layer. A portion of the third surface of the inner layer is exposed via the open area of the primary layer. A first plurality of wire bond pads are disposed on the portion of the third surface of the inner layer that is exposed via the open area of primary layer.

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 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.

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.