A system in package includes a memory-die stack in memory module that is stacked vertically with respect to a processor die. Each memory die in the memory-die stack includes a vertical bond wire that emerges from a matrix for connection. Some configurations include the vertical bond wire emerging orthogonally beginning from a bond-wire pad. The matrix encloses the memory-die stack, the spacer, and at least a portion of the processor die.

A semiconductor device package and a method for manufacturing the semiconductor device package are provided. The semiconductor device package includes a first substrate, a second substrate and an interconnection. The second substrate is arranged above the first substrate and has an opening. The interconnection passes through the opening and connects to the first substrate and the second substrate.

A semiconductor device package and a method for manufacturing the semiconductor device package are provided. The semiconductor device package includes a first substrate, a second substrate and an interconnection. The second substrate is arranged above the first substrate and has an opening. The interconnection passes through the opening and connects to the first substrate and the second substrate.

A microelectronic device, in a fan-out fan-in chip scale package, has a die and an encapsulation material at least partially surrounding the die. Fan-out connections from the die extend through the encapsulation material and terminate adjacent to the die. The fan-out connections include wire bonds, and are free of photolithographically-defined structures. Fan-in/out traces connect the fan-out connections to bump bond pads. The die and at least a portion of the bump bond pads partially overlap each other. The microelectronic device is formed by mounting the die on a carrier, and forming the fan-out connections, including the wire bonds, without using a photolithographic process. The die and the fan-out connections are covered with an encapsulation material, and the carrier is subsequently removed, exposing the fan-out connections. The fan-in/out traces are formed so as to connect to the exposed portions of the fan-out connections, and extend to the bump bond pads.

A microelectronic device, in a fan-out fan-in chip scale package, has a die and an encapsulation material at least partially surrounding the die. Fan-out connections from the die extend through the encapsulation material and terminate adjacent to the die. The fan-out connections include wire bonds, and are free of photolithographically-defined structures. Fan-in/out traces connect the fan-out connections to bump bond pads. The die and at least a portion of the bump bond pads partially overlap each other. The microelectronic device is formed by mounting the die on a carrier, and forming the fan-out connections, including the wire bonds, without using a photolithographic process. The die and the fan-out connections are covered with an encapsulation material, and the carrier is subsequently removed, exposing the fan-out connections. The fan-in/out traces are formed so as to connect to the exposed portions of the fan-out connections, and extend to the bump bond pads.

A device includes an interposer including an insulative layer between a lower metal layer and a first upper metal layer and a second upper metal layer, a semiconductor transistor die attached to the first upper metal layer and comprising a first lower main face and a second upper main face, with a drain or collector pad on the first main face and electrically connected to the first upper metal layer, a source or emitter electrode pad and a gate electrode pad on the second main face, a leadframe connected to the interposer and comprising a first lead connected with the first upper metal layer, a second lead connected with the source electrode pad, and a third lead connected with the second upper metal layer, and wherein an electrical connector that is connected between the gate electrode pad and the second upper metal layer is orthogonal to a first electrical connector.

A device includes an interposer including an insulative layer between a lower metal layer and a first upper metal layer and a second upper metal layer, a semiconductor transistor die attached to the first upper metal layer and comprising a first lower main face and a second upper main face, with a drain or collector pad on the first main face and electrically connected to the first upper metal layer, a source or emitter electrode pad and a gate electrode pad on the second main face, a leadframe connected to the interposer and comprising a first lead connected with the first upper metal layer, a second lead connected with the source electrode pad, and a third lead connected with the second upper metal layer, and wherein an electrical connector that is connected between the gate electrode pad and the second upper metal layer is orthogonal to a first electrical connector.

A Faraday cage cavity package, having: a leadframe; a plastic body molded onto the leadframe to form a cavity exposing top surfaces of a die attach paddle, tie bars and lead fingers of the leadframe within the cavity; and a lid attached onto the top of the leadframe to protect a die attached to the die attach pad from electromagnetic fields, wherein the Faraday cage cavity package is manufactured in a matrix format and then separated into a plurality of individual Faraday cage cavity package units.

A Faraday cage cavity package, having: a leadframe; a plastic body molded onto the leadframe to form a cavity exposing top surfaces of a die attach paddle, tie bars and lead fingers of the leadframe within the cavity; and a lid attached onto the top of the leadframe to protect a die attached to the die attach pad from electromagnetic fields, wherein the Faraday cage cavity package is manufactured in a matrix format and then separated into a plurality of individual Faraday cage cavity package units.

A semiconductor device and a method of forming the same are provided. The semiconductor device includes a first logic die including a first through via, an image sensor die hybrid bonded to the first logic die, and a second logic die bonded to the first logic die. A front side of the first logic die facing a front side of the image sensor die. A front side of the second logic die facing a backside of the first logic die. The second logic die comprising a first conductive pad electrically coupled to the first through via.