Abstract: Systems and methods for packaging integrated circuit chips in castellation wafer level packaging are provided. The active circuit areas of the chips are coupled to castellation blocks and, depending on the embodiment, input/output pads. The castellation blocks and input/output pads are encapsulated and held in place by an encapsulant. When the devices are being fabricated, the castellation blocks and input/output pads are sawed through. If necessary, the wafer portion on which the devices are fabricated may be thinned. The packages may be used as a leadless chip carrier package or may be stacked on top of one another. When stacked, the respective contacts of the packages are preferably coupled. Data may be written to, and received from, packaged chips when a chip is activated. Chips may be activated by applying the appropriate signal or signals to the appropriate contact or contacts.

Abstract: Methods for forming an edge contact on a die and edge contact structures are described. The edge contacts on the die do not increase the height of the die. The edge contacts are positioned on the periphery of a die. The edge contacts are positioned in the saw streets. Each edge contact is connected to one bond pad of each die adjacent the saw street. The edge contact is divided into contacts for each adjacent die when the dies are separated. In an embodiment, a recess is formed in the saw street. In an embodiment, the recess is formed by scribing the saw street with a mechanical cutter. The recess is patterned and contact material is deposited to form the edge contacts.

Abstract: Systems and methods for packaging integrated circuit chips in castellation wafer level packaging are provided. The active circuit areas of the chips are coupled to castellation blocks and, depending on the embodiment, input/output pads. The castellation blocks and input/output pads are encapsulated and held in place by an encapsulant. When the devices are being fabricated, the castellation blocks and input/output pads are sawed through. If necessary, the wafer portion on which the devices are fabricated may be thinned. The packages may be used as a leadless chip carrier package or may be stacked on top of one another. When stacked, the respective contacts of the packages are preferably coupled. Data may be written to, and received from, packaged chips when a chip is activated. Chips may be activated by applying the appropriate signal or signals to the appropriate contact or contacts.

Abstract: Semiconductor devices and assemblies including interconnects and methods for forming such interconnects are disclosed herein. One embodiment of a method of manufacturing a semiconductor device includes forming a plurality of first side trenches to an intermediate depth in a molded portion of a molded wafer having a plurality of dies arranged in rows and columns. The method also includes removing material from a second side of the molded portion at areas aligned with the first side trenches, wherein removing the material forms openings through the molded portion. The method further includes forming a plurality of electrical contacts at the second side of the molded portion at the openings and electrically connecting the second side contacts to corresponding bond-sites on the dies.

Abstract: Microelectronic die packages, stacked systems of die packages, and methods of manufacturing thereof are disclosed herein. In one embodiment, a method of manufacturing a microelectronic device includes stacking a first die package having a first dielectric casing on top of a second die package having a second dielectric casing, aligning first metal leads at a lateral surface of the first casing with second metal leads at a second lateral surface of the second casing, and forming metal solder connectors that couple individual first leads to individual second leads. In another embodiment, the method of manufacturing the microelectronic device may further include forming the connectors by applying metal solder to a portion of the first lateral surface, to a portion of the second lateral surface, and across a gap between the first die package and the second die package so that the connectors are formed by the metal solder wetting to the individual first leads and the individual second leads.

Abstract: Microelectronic die packages, stacked systems of die packages, and methods of manufacturing them are disclosed herein. In one embodiment, a system of stacked packages includes a first die package having a bottom side, a first dielectric casing, and first metal leads; a second die package having a top side attached to the bottom side of the first package, a dielectric casing with a lateral side, and second metal leads aligned with and projecting towards the first metal leads and including an exterior surface and an interior surface region that generally faces the lateral side; and metal solder connectors coupling individual first leads to individual second leads. In a further embodiment, the individual second leads have an “L” shape and physically contact corresponding individual first leads. In another embodiment, the individual second leads have a “C” shape and include a tiered portion that projects towards the lateral side of the second casing.

Abstract: Packaged semiconductor devices and assemblies including interconnects and methods for forming such interconnects are disclosed herein. One embodiment of a packaged semiconductor assembly includes a die attached to a support layer. A plurality of interconnects are embedded in and project from the support layer, such that the support layer at least partially retains the interconnects in a predetermined array. An encapsulant is molded around each of the interconnects and encases at least a portion of the die, support layer and interconnects.

Abstract: Methods for forming an edge contact on a die and edge contact structures are described. The edge contacts on the die do not increase the height of the die. The edge contacts are positioned on the periphery of a die. The edge contacts are positioned in the saw streets. Each edge contact is connected to one bond pad of each die adjacent the saw street. The edge contact is divided into contacts for each adjacent die when the dies are separated. In an embodiment, a recess is formed in the saw street. In an embodiment, the recess is formed by scribing the saw street with a mechanical cutter. The recess is patterned and contact material is deposited to form the edge contacts.

Abstract: A support structure for a semiconductor device with peripherally disposed contacts includes a support substrate and at least one conductive column protruding from the support substrate. The at least one conductive column is configured to contact an outer connector on a peripheral edge of a semiconductor device that may be carried by the support structure. Optionally, the at least one conductive column may engage a feature of (e.g., a recess in) the peripherally disposed outer connector. The at least one conductive column may facilitate alignment of one or more semiconductor devices with the support substrate alignment of semiconductor devices relative to one another, or electrical connection between multiple semiconductor devices of other components.

Abstract: Systems and methods for packaging integrated circuit chips in castellation wafer level packaging are provided. The active circuit areas of the chips are coupled to castellation blocks and, depending on the embodiment, input/output pads. The castellation blocks and input/output pads are encapsulated and held in place by an encapsulant. When the devices are being fabricated, the castellation blocks and input/output pads are sawed through. If necessary, the wafer portion on which the devices are fabricated may be thinned. The packages may be used as a leadless chip carrier package or may be stacked on top of one another. When stacked, the respective contacts of the packages are preferably coupled. Data may be written to, and received from, packaged chips when a chip is activated. Chips may be activated by applying the appropriate signal or signals to the appropriate contact or contacts.

Abstract: A multichip assembly includes semiconductor devices or semiconductor device components with outer connectors on peripheral edges thereof. The outer connectors are formed by creating via holes along boundary lines between adjacent, unsevered semiconductor devices, or semiconductor device components, then plating or filling the holes with conductive material. When adjacent semiconductor devices or semiconductor device components are severed from one another, the conductive material in each via between the semiconductor devices is bisected. The semiconductor devices and components of the multichip assembly may have different sizes, as well as arrays of outer connectors with differing diameters and pitches. Either or both ends of each outer connector may be electrically connected to another aligned outer connector or contact area of another semiconductor device or component. Assembly in this manner provides a low-profile stacked assembly.

Abstract: A semiconductor device package is disclosed which is substantially die-sized with respect to each of the X, Y and Z axes. The package includes outer connectors that are located along at least one peripheral edge thereof and that extend substantially across the height of the peripheral edge. Each outer connector is formed by severing a conductive via that extends substantially through a substrate blank, such as a silicon wafer, at a street located adjacent to an outer periphery of the semiconductor device of the package. The outer connectors may include recesses that at least partially receive conductive columns protruding from a support substrate therefor. Assemblies may include the packages in stacked arrangement, without height-adding connectors.

Abstract: Systems and methods for packaging integrated circuit chips in castellation wafer level packaging are provided. The active circuit areas of the chips are coupled to castellation blocks and, depending on the embodiment, input/output pads. The castellation blocks and input/output pads are encapsulated and held in place by an encapsulant. When the devices are being fabricated, the castellation blocks and input/output pads are sawed through. If necessary, the wafer portion on which the devices are fabricated may be thinned. The packages may be used as a leadless chip carrier package or may be stacked on top of one another. When stacked, the respective contacts of the packages are preferably coupled. Data may be written to, and received from, packaged chips when a chip is activated. Chips may be activated by applying the appropriate signal or signals to the appropriate contact or contacts.

Abstract: Methods for forming an edge contact on a die and edge contact structures are described. The edge contacts on the die do not increase the height of the die. The edge contacts are positioned on the periphery of a die. The edge contacts are positioned in the saw streets. Each edge contact is connected to one bond pad of each die adjacent the saw street. The edge contact is divided into contacts for each adjacent die when the dies are separated. In an embodiment, a recess is formed in the saw street. In an embodiment, the recess is formed by scribing the saw street with a mechanical cutter. The recess is patterned and contact material is deposited to form the edge contacts.

Abstract: Systems and methods for packaging integrated circuit chips in castellation wafer level packaging are provided. The active circuit areas of the chips are coupled to castellation blocks and, depending on the embodiment, input/output pads. The castellation blocks and input/output pads are encapsulated and held in place by an encapsulant. When the devices are being fabricated, the castellation blocks and input/output pads are sawed through. If necessary, the wafer portion on which the devices are fabricated may be thinned. The packages may be used as a leadless chip carrier package or may be stacked on top of one another. When stacked, the respective contacts of the packages are preferably coupled. Data may be written to, and received from, packaged chips when a chip is activated. Chips may be activated by applying the appropriate signal or signals to the appropriate contact or contacts.

Abstract: A microelectronic package and method for manufacture. The package can include first and second microelectronic substrates, each having a first surface with a connection site, and a second surface facing opposite the first surface. The second microelectronic substrate can be coupled to the first microelectronic substrate with the second surface of the second microelectronic substrate facing towards the first surface of the first microelectronic substrate. A conformal conductive link formed, for example, from sequentially deposited portions of conductive material, can be coupled between the first and second connection sites to provide for electrical communication between the substrates. Accordingly, the substrates can be stacked and electrically connected to reduce the footprint occupied by the substrates.

Abstract: A multichip assembly includes semiconductor devices or semiconductor device components with outer connectors on peripheral edges thereof. The outer connectors are formed by creating via holes along boundary lines between adjacent, unsevered semiconductor devices, or semiconductor device components, then plating or filling the holes with conductive material. When adjacent semiconductor devices or semiconductor device components are severed from one another, the conductive material in each via between the semiconductor devices is bisected. The semiconductor devices and components of the multichip assembly may have different sizes, as well as arrays of outer connectors with differing diameters and pitches. Either or both ends of each outer connector may be electrically connected to another aligned outer connector or contact area of another semiconductor device or component. Assembly in this manner provides a low-profile stacked assembly.

Abstract: A microelectronic package and method for manufacture. The package can include first and second microelectronic substrates, each having a first surface with a connection site, and a second surface facing opposite the first surface. The second microelectronic substrate can be coupled to the first microelectronic substrate with the second surface of the second microelectronic substrate facing towards the first surface of the first microelectronic substrate. A conformal conductive link formed, for example, from sequentially deposited portions of conductive material, can be coupled between the first and second connection sites to provide for electrical communication between the substrates. Accordingly, the substrates can be stacked and electrically connected to reduce the footprint occupied by the substrates.

Abstract: The present invention is directed to a leadless and interconnected semiconductor package. The package includes a first chip having bond pads with a second chip having bond pads positioned on the first chip to form a vertically stacked package. Interconnections between the bond pads are formed by metallized layers on the package that extend to an edge of the package to join castellations along sides of the package to form a plurality of leadless input/output locations for the package. In one embodiment, the castellations include planar metallized portions. In another embodiment, the castellations include semi-cylindrical metallized portions. In still another embodiment, insulators are positioned between the chips, and on the package base. In still another embodiment, a chip includes a photosensitive device having screening optical layers. Bond pads on the chip are electrically coupled to castellations extending from the bond pads to form leadless input/output locations for the package.

Abstract: The present invention is directed to a leadless and interconnected semiconductor package. The package includes a first chip having bond pads with a second chip having bond pads positioned on the first chip to form a vertically stacked package. Interconnections between the bond pads are formed by metallized layers on the package that extend to an edge of the package to join castellations along sides of the package to form a plurality of leadless input/output locations for the package. In one embodiment, the castellations include planar metallized portions. In another embodiment, the castellations include semi-cylindrical metallized portions. In still another embodiment, insulators are positioned between the chips, and on the package base. In still another embodiment, a chip includes a photosensitive device having screening optical layers. Bond pads on the chip are electrically coupled to castellations extending from the bond pads to form leadless input/output locations for the package.