Abstract: A method of manufacturing a lead frame includes providing an electrically conductive layer having a plurality of holes at a top surface. The plurality of holes form a structure of leads and a die pad on the electrically conductive layer. The plurality of holes are filled with a non-conductive material. Next; an electrically conductive foil is attached on the top surface of the electrically conductive layer and the non-conductive epoxy material. The, the electrically conductive foil is etched to create a network of leads, die pad, bus lines, dam bars and tie lines, wherein the bus lines connect the leads to the dam bar, the dam bar is connected to the tie line and the tie line is connected to the die pad.

Abstract: Wafer-level package (semiconductor) devices are described that have a reinforcement layer formed on an adhesion layer and/or a semiconductor substrate and covering at least a portion of at least one solder bump. Additionally, the reinforcement layer may cover at least a portion of a semiconductor device (e.g., a die) mounted on the semiconductor substrate. In an implementation, the wafer-level package (semiconductor) device may include an integrated circuit chip with an attached die, where the integrated circuit chip has at least one solder bump formed thereon with a reinforcement layer formed on a surface of the integrated circuit chip, where the reinforcement layer embeds the die and covers a portion of the at least one solder bump.

Abstract: A method of manufacturing a lead frame includes providing an electrically conductive layer having a plurality of holes at a top surface. The plurality of holes form a structure of leads and a die pad on the electrically conductive layer. The plurality of holes are filled with a non-conductive material. Next; an electrically conductive foil is attached on the top surface of the electrically conductive layer and the non-conductive epoxy material. The, the electrically conductive foil is etched to create a network of leads, die pad, bus lines, dam bars and tie lines, wherein the bus lines connect the leads to the dam bar, the dam bar is connected to the tie line and the tie line is connected to the die pad.

Abstract: A semiconductor package device, electronic device, and fabrication methods are described that include at least one sacrificial contact pad as a portion of the semiconductor package device for preventing and reducing stress on the semiconductor package device and increasing board level reliability. In implementations, the semiconductor package device includes a lead frame substrate including at least one lead frame contact pad and at least one sacrificial contact pad, an integrated circuit device electrically coupled to the lead frame substrate, and an encapsulation layer that encapsulates the lead frame substrate and the integrated circuit device.

Abstract: A method of manufacturing a lead frame includes providing an electrically conductive layer having a plurality of holes at a top surface. The plurality of holes form a structure of leads and a die pad on the electrically conductive layer. The plurality of holes are filled with a non-conductive material. Next; an electrically conductive foil is attached on the top surface of the electrically conductive layer and the non-conductive epoxy material. Then, the electrically conductive foil is etched to create a network of leads, die pad, bus lines, dam bars and tie lines, wherein the bus lines connect the leads to the dam bar, the dam bar is connected to the tie line and the tie line is connected to the die pad.

Abstract: Semiconductor devices are described that have an extended under ball metallization configured to mitigate dielectric layer cracking due to stress, particularly stress caused by CTE mismatch during thermal cycling tests, dynamic deformation during drop tests, or cyclic bending tests, and so on. In an implementation, the semiconductor package devices include an integrated circuit chip having a solder ball and under ball metallization, formed on the integrated circuit chip, which is configured to receive the solder ball so that the solder ball and the under ball metallization have a contact area there between, wherein the area of the under ball metallization is area greater than the contact area.

Abstract: Wafer-level package (semiconductor) devices are described that have a pillar structure that extends at least partially into a solder bump to mitigate thermal stresses to the solder bump. In implementations, the wafer-level package device may comprise an integrated circuit chip having a surface and a solder bump disposed over the surface. The wafer-level package device may also include a pillar structure disposed over the surface that extends at least partially into the solder bump.

Abstract: Wafer-level package (semiconductor) devices are described that have a pillar structure that extends at least partially into a solder bump to mitigate thermal stresses to the solder bump. In implementations, the wafer-level package device may comprise an integrated circuit chip having a surface and a solder bump disposed over the surface. The wafer-level package device may also include a pillar structure disposed over the surface that extends at least partially into the solder bump.

Abstract: Semiconductor devices are described that have an extended under ball metallization configured to mitigate dielectric layer cracking due to stress, particularly stress caused by CTE mismatch during thermal cycling tests, dynamic deformation during drop tests, or cyclic bending tests, and so on. In an implementation, the semiconductor package devices include an integrated circuit chip having a solder ball and under ball metallization, formed on the integrated circuit chip, which is configured to receive the solder ball so that the solder ball and the under ball metallization have a contact area there between, wherein the area of the under ball metallization is area greater than the contact area.

Abstract: An integrated circuit package having a die pad with a first face and a second face, a plurality of inner leads, and a plurality of sides between the first face and the second face. The plurality of inner leads is disposed substantially co-planer with and substantially around the die pad. The package also comprises a plurality of outer leads disposed substantially co-planar with and substantially around the plurality of inner leads and the die pad, so that the sides of each of the plurality of outer leads are offset from the sides of each of the plurality of inner leads. A first adhesive layer disposed on the first face of the die pad and a second adhesive layer disposed on the first faces of each of the plurality of inner leads. An IC chip is coupled to the first face of the die pad through the first adhesive layer and to the plurality of inner leads through the second adhesive layer. The package further comprises wires linking the inner leads and outer leads to the IC chip.

Abstract: An interposer is presented. The interposer includes an interposer base having first and second surfaces. A redistribution layer is disposed on a first surface of the interposer base. The interposer has at least one interposer pad coupled to the redistribution layer. It also includes at least one interposer contact on the second surface. The interposer contact is electrically coupled to the interposer pad via the redistribution layer. The interposer also includes at least one interposer via through the interposer base for coupling the interposer contact to the redistribution layer. The interposer via includes reflowed conductive material of the interposer contact.

Abstract: A semiconductor package with a semiconductor chip having under bump metallizations (UBMs) on a first surface and a substrate having open vias. The substrate is attached to the semiconductor chip with the UBMs in alignment with the open vias. An encapsulant surrounds the semiconductor chip and the substrate and a conductor fills the open vias to form external package connections.

Abstract: The present invention relates to semiconductor devices comprising two or more dies stacked vertically on top of one another, and methods of making the semiconductor devices. The methods may comprise a combination of wafer-level through silicon interconnect fabrication and wafer-level assembly processes.

Abstract: A chip scale integrated circuit package includes an integrated circuit chip which has a first face and a second face. A plurality of pillar bumps are formed on the first face of the integrated circuit chip. An encapsulant material encapsulates the sides and the first face of the integrated circuit chip, and the pillar bumps. Upper ends of the pillar bumps remain free from encapsulant material and a substantially planar surface is formed by an upper surface of the encapsulant material and the upper ends of the pillar bumps. A plurality of solder balls are mounted on the substantially planar surface in locations corresponding to the upper ends of the pillar bumps.

Abstract: A method for of manufacturing integrated circuit packages and a multi-chip integrated circuit package are disclosed. According to the method, a first die is attached onto a first side of a set of leads of a leadframe, and an adhesive is applied onto the set of leads at a second side opposite to the first side. A second die is attached onto the adhesive. The adhesive fills into the gaps defined by the set of leads. The adhesive is thereafter cured. In a multi-chip integrated circuit package made according to the method, the adhesive attaching the second die fills the gaps between the leads so that to avoid formation of internal cavities of the package.

Abstract: A stacked die semiconductor package that includes a substrate with a plurality of adhesive portions arranged in a manner to create at least one gap between the adhesive portions. The package also includes a first semiconductor chip having a non-active surface in contact with the adhesive portions, and an active surface being electrically connected to the substrate. In the package, a second semiconductor chip the non-active surface of the second semiconductor chip is attached to the non-active surface of the first semiconductor chip by a layer of adhesive therebetween. The active surface of the second semiconductor chip is electrically connected to the substrate. An encapsulant material covers the first and second semiconductor chips and their associated electrical connections. The encapsulating material fills the at least one gap between the plurality of adhesive portions and thereby encapsulates the second semiconductor chip and its associated electrical connection.

Abstract: A stiffener is provided for use in making semiconductor devices. The stiffener and method of use provided prevent or reduce warpage of a semiconductor package during the assembly process. More particularly, the stiffener functions to prevent or reduce warpage during molding of an assembly of wafers and/or dies. The stiffener may be positioned above the backside or non-active side of an assembly of wafer and/or dies during molding. The presence of the stiffener prevents or reduces warpage caused by CTE mismatch between the mold material and the wafer and/or under the high temperatures encountered in the process of molding. After molding, the stiffener may continue to provide support to the assembly.

Abstract: A semiconductor chip package and method of making the same. A first chip unit includes a first substrate and a first IC chip electrically connected to the first substrate. A second chip unit includes a second substrate and a second IC chip electronically connected to the second substrate. An adhesive material is provided on a surface of the first IC chip and the second chip unit is mounted onto the surface of the first chip unit including the adhesive material so that at least a portion of the second structure is encapsulated by the adhesive material, thereby providing some encapsulation in the same step as mounting. The first chip unit and the second chip unit may be separated by a spacer which may also provide an electrical connection.

Abstract: The present invention relates to semiconductor devices comprising two or more dies stacked vertically on top of one another, and methods of making the semiconductor devices. The methods may comprise a combination of wafer-level through silicon interconnect fabrication and wafer-level assembly processes.

Abstract: A semiconductor package includes a plurality of first leads, each with a top outer portion removed from the lead and an outer end, and a plurality of second leads, each with a bottom outer portion removed from the lead and an outer end. The first and second leads alternate with each other along an edge of the package. Also, the outer ends of the first leads form a first row along the edge of the package and the outer ends of the second leads form a second row along the edge of the package. In one embodiment, the first and second rows are parallel to each other and an encapsulant covers at least a portion of the first and second leads.