A semiconductor device assembly is provided. The assembly includes an outer semiconductor device which has an active surface and a back surface. The back surface includes a cut that extends to a depth between the active surface and the back surface, and uncut regions on opposing sides of the cut. The assembly further includes an inner semiconductor device disposed within the cut of the outer semiconductor device.

A semiconductor device includes first and second chips in a package. A first pad is on the first chip and electrically connected to a node between a power supply pad and a ground pad on the first chip. Second and third pads are on the second chip. An internal wiring connects the first pad to the second pad within the package. A power circuit on the semiconductor chip configured to supply a current to the second pad. A switch is on the second chip between the second pad and the power supply circuit to connect or disconnect the second pad from the power circuit. A control circuit is on the second chip and configured to output a first signal for the switch in response to a test signal supplied to the third pad and a second signal to the power circuit to cause the power circuit to output current.

Provided is a semiconductor package including a first substrate having an upper surface and a lower surface, and including a substrate pad arranged on the upper surface, a first chip stacked structure mounted on the upper surface of the first substrate, and including a plurality of first chips offset-stacked in a first direction, a lowermost first wire electrically connecting a lowermost first chip to the substrate pad, and a second chip stacked structure mounted on the upper surface of the first substrate, and including a plurality of second chips offset-stacked in the first direction, wherein the second chip stacked structure is spaced apart from the first chip stacked structure with the lowermost first wire therebetween in a horizontal direction, and an upper surface of a lowermost second chip is at a higher vertical direction level than a highest level of the lowermost first wire in a vertical direction.

A method of manufacturing a semiconductor device is provided. The method includes attaching a first die pad of a semiconductor die to a central pad of a package leadframe. The first die pad is located in a central region on an active side of the semiconductor die. A second die pad of the semiconductor die is connected a lead of the package lead frame. The second die pad is located in a periphery region on the active side of the semiconductor die. An encapsulant encapsulates a portion of the semiconductor die and a portion of the package leadframe. A backside surface of the semiconductor die is exposed at a top major surface of the encapsulant, and a backside surface of the central pad exposed at a bottom major surface of the encapsulant.

An apparatus may include a controller die configured to communicate with a plurality of dies via a transmission line. The controller die may be configured to transmit a signal on the transmission line to a target die of the plurality of dies, or the target die may transmit a signal on the transmission line. The transmission may be dependent on an end die of the plurality of dies setting an end-die termination resistance to a low level. In situations where the target memory is receiving the signal, the target die may set target an on-die termination resistance to a high level. In situations where the target memory die is transmitting the signal, the target die may set an on-die termination resistance to a low level.

Apparatus(es) and method(s) relate generally to via arrays on a substrate. In one such apparatus, the substrate has a conductive layer. First plated conductors are in a first region extending from a surface of the conductive layer. Second plated conductors are in a second region extending from the surface of the conductive layer. The first plated conductors and the second plated conductors are external to the first substrate. The first region is disposed at least partially within the second region. The first plated conductors are of a first height. The second plated conductors are of a second height greater than the first height. A second substrate is coupled to first ends of the first plated conductors. The second substrate has at least one electronic component coupled thereto. A die is coupled to second ends of the second plated conductors. The die is located over the at least one electronic component.

A semiconductor package includes a substrate, a substrate pad on an upper surface of the substrate, first and second semiconductor chips stacked on the substrate in a first direction, wherein a sidewall of the first semiconductor chip and a sidewall of the second semiconductor chip are on the same plane, a first chip stack pad on an upper surface of the first semiconductor chip, a second chip stack pad on an upper surface of the second semiconductor chip, a first wire connecting the first chip stack pad with the substrate pad, and a second wire connecting the second chip stack pad with the substrate pad, wherein a first center of an upper surface of the first chip stack pad and a second center of an upper surface of the second chip stack pad are misaligned in the first direction.

Stacked microfeature devices and associated methods of manufacture are disclosed. A package in accordance with one embodiment includes first and second microfeature devices having corresponding first and second bond pad surfaces that face toward each other. First bond pads can be positioned at least proximate to the first bond pad surface and second bond pads can be positioned at least proximate to the second bond pad surface. A package connection site can provide electrical communication between the first microfeature device and components external to the package. A wirebond can be coupled between at least one of the first bond pads and the package connection site, and an electrically conductive link can be coupled between the first microfeature device and at least one of the second bond pads of the second microfeature device. Accordingly, the first microfeature device can form a portion of an electrical link to the second microfeature device.

Systems and methods for providing a low profile stacked die semiconductor package in which a first semiconductor package is stacked with a second semiconductor package and both semiconductor packages are conductively coupled to an active silicon substrate that communicably couples the first semiconductor package to the second semiconductor package. The first semiconductor package may conductively couple to the active silicon substrate using a plurality of interconnects disposed in a first interconnect pattern having a first interconnect pitch. The second semiconductor package may conductively couple to the active silicon substrate using a plurality of interconnects disposed in a second interconnect pattern having a second pitch that is greater than the first pitch. The second semiconductor package may be stacked on the first semiconductor package and conductively coupled to the active silicon substrate using a plurality of conductive members or a plurality of wirebonds.

A memory system having a dynamic supply voltage to sense amplifiers. The supply voltage has a higher magnitude when charging inhibited bit lines during a program operation and a lower magnitude when verifying/sensing memory cells. Reducing the magnitude of the supply voltage saves power and/or current. However, if the lower magnitude were used when the inhibited bit lines are charged during the program operations, some of the memory cells that should be inhibited from programming might experience at least some programming. Using the higher magnitude supply voltage during bit line charging of the program operation assures that the inhibited bit lines are charged to a sufficient voltage to keep drain side select gates of NAND strings off so that the NAND channel will boost properly to inhibit programming of such memory cells.