Abstract: Stacked microelectronic devices and methods for manufacturing such devices. An embodiment of a microelectronic device can include a support member and a first known good microelectronic die attached to the support member. The first die includes an active side, a back side, a first terminal, and integrated circuitry electrically coupled to the first terminal. The first die also includes a first redistribution structure at the active side. The microelectronic device can also include a second known good microelectronic die attached to the first die in a stacked configuration with a back side of the second die facing the support member and an active side of the second die facing away from the support member. The second die includes a second redistribution structure at the active side. The device can further include a casing covering the first die, the second die, and at least a portion of the support member.

Abstract: Circuit boards, microelectronic devices, and other apparatuses having slanted vias are disclosed herein. In one embodiment, an apparatus for interconnecting electronic components includes a dielectric portion having a first surface and a second surface. A first terminal is disposed on the first surface of the dielectric portion for connection to a first electronic component. A second terminal is disposed on the second surface of the dielectric portion for connection to a second electronic component. The apparatus further includes a passage extending through the dielectric portion along a longitudinal axis oriented at an oblique angle relative to the first surface. The passage is at least partially filled with conductive material electrically connecting the first terminal to the second terminal.

Abstract: Chip-scale packages and assemblies thereof are disclosed. The chip-scale package includes a core member of a metal or alloy having a recess for at least partially receiving a die therein and includes at least one flange member partially folded over another portion of the core member. Conductive traces extend from one side of the package over the at least one flange member to an opposing side of the package. Systems including the chip-scale packages and assemblies are also disclosed.

Abstract: Methods of fabrication of lead frame-based semiconductor device packages including at least one land grid array package. At least one semiconductor die is mounted to an interposer substrate, with bond pads of the semiconductor die connected to terminal pads of the interposer substrate. The terminal pads of the interposer substrate may be electrically connected to both a peripheral array pattern of lands and to a central, two-dimensional array pattern of pads, both array patterns located on an opposing side of the interposer substrate from the at least one semiconductor die. The at least one semiconductor die is overmolded with an encapsulant, leaving the opposing side of the interposer substrate free of encapsulant. Lead fingers of a lead frame superimposed on the opposing side of the interposer substrate are bonded directly to the land grid array lands.

Abstract: Chip-scale packages and assemblies thereof and methods of fabricating such packages including Chip-On-Board, Board-On-Chip, and vertically stacked Package-On-Package modules are disclosed. The chip-scale package includes a core member of a metal or alloy having a recess for at least partially receiving a die therein and includes at least one flange member partially folded over another portion of the core member. Conductive traces extend from one side of the package over the at least one flange member to an opposing side of the package. Systems including the chip-scale packages and assemblies are also disclosed.

Abstract: A device is disclosed which includes a first packaged integrated circuit device, a second packaged integrated circuit device positioned above the first packaged integrated circuit device and a plurality of planar conductive members conductively coupling the first and second packaged integrated circuit devices to one another. A method is also disclosed which includes conductively coupling a plurality of extensions on a leadframe to each of a pair of stacked packaged integrated circuit devices and cutting the leadframe to singulate the extensions from one another.

Abstract: Circuit boards, microelectronic devices, and other apparatuses having slanted vias are disclosed herein. In one embodiment, an apparatus for interconnecting electronic components includes a dielectric portion having a first surface and a second surface. A first terminal is disposed on the first surface of the dielectric portion for connection to a first electronic component. A second terminal is disposed on the second surface of the dielectric portion for connection to a second electronic component. The apparatus further includes a passage extending through the dielectric portion along a longitudinal axis oriented at an oblique angle relative to the first surface. The passage is at least partially filled with conductive material electrically connecting the first terminal to the second terminal.

Abstract: A device is disclosed which includes an interposer, at least one capacitor formed at least partially within an opening formed in the interposer and an integrated circuit that is operatively coupled to the interposer. A method is disclosed which includes obtaining an interposer having at least one capacitor formed at least partially within an opening in the interposer and operatively coupling an integrated circuit to the interposer. A method is also disclosed which includes obtaining an interposer comprising a dielectric material, forming an opening in the interposer and forming a capacitor that is positioned at least partially within the opening.

Abstract: Packaged semiconductor components, apparatus for packaging semiconductor devices, methods of packaging semiconductor devices, and methods of manufacturing apparatus for packaging semiconductor devices. One embodiment of an apparatus for packaging semiconductor devices comprises a first board having a front side, a backside, arrays of die contacts, arrays of first backside terminals electrically coupled to the die contacts, arrays of second backside terminals, and a plurality of individual package areas that have an array of the die contacts, an array of the first backside terminals, and an array of the second backside terminals.

Abstract: Chip-scale packages and assemblies thereof and methods of fabricating such packages including Chip-On-Board, Board-On-Chip, and vertically stacked Package-On-Package modules are disclosed. The chip-scale package includes a core member of a metal or alloy having a recess for at least partially receiving a die therein and includes at least one flange member partially folded over another portion of the core member. Conductive traces extend from one side of the package over the at least one flange member to an opposing side of the package. Systems including the chip-scale packages and assemblies are also disclosed.

Abstract: A device is disclosed which includes a flexible material including at least one conductive wiring trace, a first die including at least an integrated circuit, the first die being positioned above a portion of the flexible material, and an encapsulant material that covers the first die and at least a portion of the flexible material. A method is disclosed which includes positioning a first die above a portion of a flexible material, the first die including an integrated circuit and the flexible material including at least one conductive wiring trace, and forming an encapsulant material that covers the first die and at least a portion of the flexible material, wherein at least a portion of the flexible material extends beyond the encapsulant material.

Abstract: Semiconductor device assemblies and systems that include at least one semiconductor device assembly include two or more semiconductor devices stacked one over another. Conductive pathways that extend around at least one side of at least one of the semiconductor devices provide electrical communication between conductive elements of the semiconductor devices, and optionally, a substrate. The conductive pathways may include self-supporting conductive leads or conductive traces carried by a substrate. Methods for forming semiconductor device assemblies having more than one semiconductor device include bending or wrapping at least one conductive pathway around a side of at least one semiconductor device and providing electrical communication between semiconductor devices of the assembly through the conductive pathways.

Abstract: A method for designing a carrier substrate includes configuring at least one die-attach location and one or more terminals that protrude from a surface of the carrier substrate so as to prevent adhesive material from contaminating connection surfaces thereof. The method may also include configuring the carrier substrate to include one or more recessed areas that laterally surround at least a portion of the die-attach location to receive excess adhesive.

Abstract: Chip scale packages and assemblies thereof and methods of fabricating such packages including Chip-On-Board, Board-On-Chip, and vertically stacked Package-On-Package modules are disclosed. The chip scale package includes a core member of a metal or alloy having a recess for at least partially receiving a die therein and includes at least one flange member partially folded over another portion of the core member. Conductive traces extend from one side of the package over the at least one flange member to an opposing side of the package. Systems including the chip scale packages and assemblies are also disclosed.

Abstract: Pre-encapsulated lead frames suitable for use in microelectronic device packages are disclosed. Individual lead frames can include a set of multiple lead fingers arranged side by side with neighboring lead fingers spaced apart from each other by a corresponding gap. An encapsulating compound at least partially encapsulates the set of lead fingers without encapsulating a microelectronic device. The encapsulating compound can generally fill the plurality of gaps between two adjacent lead fingers.

Abstract: Substrates for mounting microelectronic dies, methods for forming vias in such substrates, and methods for packaging microelectronic devices are disclosed herein. A method of manufacturing a substrate in accordance with one embodiment of the invention includes forming a conductive trace on a first side of a sheet of non-conductive material, and forming a via through the non-conductive material from a second side of the sheet to the conductive trace. The method further includes removing a section of the non-conductive material to form an edge of the non-conductive material extending across at least a portion of the via. In one embodiment, forming the edge across the via exposes at least a portion of the second conductive trace for subsequent attachment to a terminal on a microelectronic die.

Abstract: Microelectronic packages with leadframes, including leadframes configured for stacked die packages, and associated systems and methods are disclosed. A system in accordance with one embodiment includes a support member having first package bond sites electrically coupled to leadframe bond sites. A microelectronic die can be carried by the support member and electrically coupled to the first packaged bond sites. A leadframe can be attached to the leadframe bond sites so as to extend adjacent to the microelectronic die, with the die positioned between the leadframe and the support member. The leadframe can include second package bond sites facing away from the first package bond sites. An encapsulant can at least partially surround the leadframe and the microelectronic die, with the first and second package bond sites accessible from outside the encapsulant.

Abstract: Packaged microelectronic devices recessed in support member cavities, and associated methods, are disclosed. Method in accordance with one embodiment includes positioning a microelectronic device in a cavity of a support member, with the cavity having a closed end with a conductive layer, and an opening through which the cavity is assessable. The microelectronic device can have bond sites, a first surface, and a second surface facing opposite from the first surface. The microelectronic device can be positioned in the cavity so that the second surface faces toward and is carried by the conductive layer. The method can further include electrically coupling the bond sites of the microelectronic device to the conductive layer. In particular embodiments, the microelectronic device can be encapsulated in the cavity without the need for a releasable tape layer to temporarily support the microelectronic device.

Abstract: Microelectronic device assemblies, including assemblies with recurved leadframes, and associated methods are disclosed. An assembly in accordance with one embodiment includes a microelectronic device having a first surface, a second surface facing opposite from the first surface, and a plurality of bond sites accessible from the first surface. An operable microelectronic feature can be located between the first and second surfaces. The assembly can further include a leadframe positioned proximate to the microelectronic device, with the leadframe having a plurality of conductive leadfingers, each being electrically coupled to a corresponding bond site of the microelectronic device, and extending around the microelectronic device to face toward the second surface. This arrangement can be used to support single microelectronic devices, and/or stacked microelectronic devices.

Abstract: Circuit boards, microelectronic devices, and other apparatuses having slanted vias are disclosed herein. In one embodiment, an apparatus for interconnecting electronic components includes a dielectric portion having a first surface and a second surface. A first terminal is disposed on the first surface of the dielectric portion for connection to a first electronic component. A second terminal is disposed on the second surface of the dielectric portion for connection to a second electronic component. The apparatus further includes a passage extending through the dielectric portion along a longitudinal axis oriented at an oblique angle relative to the first surface. The passage is at least partially filled with conductive material electrically connecting the first terminal to the second terminal.