A stack package includes a package substrate having a bond finger and a stack of a first semiconductor die and a second semiconductor die. The first semiconductor die includes a first pad, a second pad, and a first redistributed line connecting the first and second pads to each other. The second semiconductor die includes a third pad, a fourth pad, and a second redistributed line connecting the third and fourth pads to each other. The first and third pads are connected to each other by a first interconnector which is bonded to the bond finger, and the second and fourth pads are connected to each other by a second interconnector.

An integrated circuit provides a semiconductor die with I/O bond pads, a power bond pad, and a circuit ground pad. Each I/O bond pad is associated with an input circuit that has an input circuit output lead. Sets of digital logic functional circuitry on the die provide different digital logic functions. Each function includes logic input leads and logic output leads. Output circuits each have an output circuit in lead and an output circuit out lead. Strapping structures, such as vias, formed in the semiconductor die electrically couple input circuits to a selected set of digital logic functions and the selected set of digital logic functions to output circuit in leads. Upper level metal conductors couple output circuit out leads and selected I/O bond pads.

At least one circuit element may be formed on a front side of a ringed substrate, and the ringed substrate may be mounted on a mounting chuck. The mounting chuck may have an inner raised portion configured to receive the thinned portion of the substrate thereon, and a recessed ring around a perimeter of the mounting chuck configured to receive the outer ring of the ringed substrate therein. At least one solder bump may be formed that is electrically connected to the at least one circuit element, while the ringed wafer is disposed on the mounting chuck.

An integrated circuit chip is attached to a support that includes first conductive elements. First conductive pads are located on the integrated circuit chip and are electrically coupled to the first conductive elements by conductive wires. The integrated circuit chip further includes a conductive track. A switch circuit is provided to selectively electrically connect each first conductive pad to the conductive track. To test the conductive wires, a group of first conductive pads are connected by their respective switch circuits to the conductive track and current flow between corresponding first conductive elements is measured.

A method includes forming a first polymer layer over a plurality of metal pads, and patterning the first polymer layer to forming a plurality of openings in the first polymer layer. The plurality of metal pads are exposed through the plurality of openings. A plurality of conductive vias are formed in the plurality of openings. A plurality of conductive pads are formed over and contacting the plurality of conductive vias. A conductive pad in the plurality of conductive pads is laterally shifted from a conductive via directly underlying, and in physical contact with, the conductive pad. A second polymer layer is formed to cover and in physical contact with the plurality of conductive pads.

A semiconductor package includes a first chip and a second chip arranged side by side on a carrier substrate. The first chip is provided with a high-speed signal pads along a first side in proximity to the second chip. The second chip includes a redistribution layer, and the redistribution layer is provided with data (DQ) pads along the second side in proximity to the first chip. A plurality of first bonding wires is provided to directly connect the high-speed signal pads to the DQ pads. The redistribution layer of the second chip is provided with first command/address (CA) pads along the third side opposite to the second side, and a plurality of dummy pads corresponding to the first CA pads. The plurality of dummy pads are connected to second CA pads disposed along a fourth side of the second chip via interconnects of the redistribution layer.

An electronic device package includes a circuit layer, a first semiconductor die, a second semiconductor die, a plurality of first conductive structures and a second conductive structure. The first semiconductor die is disposed on the circuit layer. The second semiconductor die is disposed on the first semiconductor die, and has an active surface toward the circuit layer. The first conductive structures are disposed between a first region of the second semiconductor die and the first semiconductor die, and electrically connecting the first semiconductor die to the second semiconductor die. The second conductive structure is disposed between a second region of the second semiconductor die and the circuit layer, and electrically connecting the circuit layer to the second semiconductor die.

The present application discloses a semiconductor device and a method for fabricating the semiconductor device. The semiconductor device includes a first substrate including a center region and an edge region distal from the center region, a first circuit layer positioned on the first substrate, a center power pad positioned in the first circuit layer and above the center region, an edge power pad positioned in the first circuit layer, above the edge region, and electrically coupled to the center power pad, a redistribution power pattern positioned above the first circuit layer and electrically coupled to the center power pad, and an edge power via positioned between the edge power pad and the redistribution power pattern, and electrically connecting the edge power pad and the redistribution power pattern. The first substrate, the center power pad, the edge power pad, the redistribution power pattern, and the edge power via together configure a first semiconductor die.

A semiconductor device includes: a wiring board including first to third bonding pads; a chip stack including semiconductor chips, each chip having first to third connection pads, the first connection pads being connected in series to each other and to the first bonding pad through first bonding wires to form a first transmission channel, the second connection pads being connected in series to each other and to the second bonding pad through second bonding wires to form a second transmission channel, and the third connection pads being connected in series to each other and to the third bonding pad through third bonding wires to form a third transmission channel; and at least one of a first and a second terminating resistor being provided above the chip stack, the first resistor being connected to the first and second channels, the second resistor being connected to the first and third channels.

A lead frame for a multi-chip module includes a first conductor structure disposed on a substrate and having first and second arms linked at an angle. The first conductor structure is connected to ground. The lead frame also includes a second conductor structure disposed on the substrate and connected to a voltage supply. The second conductor structure is spaced apart and electrically isolated from the first conductor structure. The first and the second conductor structures are arranged to flank a plurality of integrated circuits (ICs) including one or more surge protection ICs disposed on the substrate. The first conductor structure is electrically connected to the plurality of ICs to provide electrical connections to ground, and the second conductor structure is electrically connected to the plurality of ICs to provide electrical connections to the voltage supply.