Abstract: A method for insulating a bonding wire that includes the steps of attaching a bonding wire to a bond pad and coating the bonding wire with an insulating liquid while drawing the bonding wire through a bond tool from the bond pad to a package lead.

Abstract: An integrated circuit with a pressure resistant current carrying structure having electrically conductive layers for carrying current. A first electrically nonconductive material at least partially surrounds the electrically conductive layers, and provides electrical insulation between the electrically conductive layers. The first electrically nonconductive material has a first degree of fragility and a first dielectric constant. A second electrically nonconductive material is disposed in a pattern within the first electrically nonconductive material and between the electrically conductive layers, and provides structural support for the first electrically nonconductive material between the electrically conductive layers. The second electrically nonconductive material has a second degree of fragility that is less than the first degree of fragility and a second dielectric constant that is greater than the first dielectric constant.

Abstract: An integrated circuit having a top passivation layer and bonding pads, where the improvement is a metal layer overlying all of the integrated circuit. The metal layer overlies the top passivation layer and is not in electrical contact with any of the bonding pads. In this manner, there is a structure that is added to the integrated circuit which has a relatively high thermal conductivity, and which also has a relatively high structural strength. With these two added properties, the occurrence of stress cracks, such as those induced by plastic molded packages, is reduced, and hot spots tend to be dissipated. Thus, the overlying metal layer tends to improve the reliability of the integrated circuit.

Abstract: A method for insulating a bonding wire that includes the steps of attaching a bonding wire to a bond pad and coating the bonding wire with an insulating liquid while drawing the bonding wire through a bond tool from the bond pad to a package lead.

Abstract: A wire bond assembly includes a multitude of bond pads arranged in an array on the surface of a die among the active circuitry and wires for electrically connecting the bond pads on the die to the substrate. As the bond pads on the die are not limited to the perimeter of the die a greater density of bond pads can be achieved and therefore the overall dimensions of the die can be reduced.

Abstract: An integrated circuit with a pressure resistant current carrying structure having electrically conductive layers for carrying current. A first electrically nonconductive material at least partially surrounds the electrically conductive layers, and provides electrical insulation between the electrically conductive layers. The first electrically nonconductive material has a first degree of fragility and a first dielectric constant. A second electrically nonconductive material is disposed in a pattern within the first electrically nonconductive material and between the electrically conductive layers, and provides structural support for the first electrically nonconductive material between the electrically conductive layers. The second electrically nonconductive material has a second degree of fragility that is less than the first degree of fragility and a second dielectric constant that is greater than the first dielectric constant.

Abstract: An integrated circuit, including a substrate with circuitry formed therein, where the substrate has a peripheral edge. Also included are a top most electrically conductive layer and an underlying electrically conductive layer. Outer bonding pads are disposed in an outer ring, and are formed within the top most layer. Inner bonding pads are disposed in an inner ring, and are formed within the top most layer. Inner connectors electrically connect the inner bonding pads to the circuitry. The inner connectors are formed within the underlying layer, and have a width that is less than the width of the inner bonding pads, thereby defining a gap between the inner connectors. Outer connectors electrically connect the outer bonding pads to the circuitry. The outer connectors are formed within the underlying layer, and have a width that is less than the width of the gap between the inner connectors.

Abstract: An integrated circuit having a top passivation layer and bonding pads, where the improvement is a metal layer overlying all of the integrated circuit. The metal layer overlies the top passivation layer and is not in electrical contact with any of the bonding pads. In this manner, there is a structure that is added to the integrated circuit which has a relatively high thermal conductivity, and which also has a relatively high structural strength. With these two added properties, the occurrence of stress cracks, such as those induced by plastic molded packages, is reduced, and hot spots tend to be dissipated. Thus, the overlying metal layer tends to improve the reliability of the integrated circuit.

Abstract: A method for insulating a bonding wire that includes the steps of attaching a bonding wire to a bond pad and coating the bonding wire with an insulating liquid while drawing the bonding wire through a bond tool from the bond pad to a package lead.

Abstract: An integrated circuit package includes a connector board and plural levels of individual conductors and conductive vias disposed through the connector board to form electrical connections between external connection pads on an undersurface of the connector board and finger connections on the upper surface of the connector board. An integrated circuit die is mounted in a central region of the connector board within confines of the individual conductors that are arranged about the die, and wire bond connections are formed between selected ones of the finger connections, the individual conductors, and the connection pads on the integrated circuit die to provide distributed connections for ground and power at one or more operating voltage levels on the individual conductors.

Abstract: A mold for use in encapsulating an integrated circuit, wherein an encapsulant is injected into the mold during packaging of the integrated circuit. The improvement to the mold is a shaped member having an abutting surface for contacting a surface of the integrated circuit and thereby substantially preventing encapsulant from adhering to the surface of the integrated circuit, whereby the surface of the integrated circuit is left exposed. Because the surface of the integrated circuit is left exposed, the encapsulant used to encapsulate the integrated circuit does not form a thermal barrier between the integrated circuit and the exterior of the package. Thus, the packaged integrated circuit is able to more efficiently conduct heat away from the integrated circuit.

Abstract: An integrated circuit package manufacturing process is described which reduces or eliminates the formation of voids in a molding compound between a die and an underlying substrate. The process includes providing the substrate, which has an upper surface and an air space above the upper surface. Electrically conductive vias are formed through the upper surface of the substrate which extend at least partially through the substrate, and fluid communication is provided between the vias and the overlying air space. The process includes attaching the integrated circuit die to the upper surface of the substrate over at least a portion of the vias, while leaving a gap between the die and the upper surface of the substrate. The process further includes flowing the molding compound into the gap between the die and the upper surface of the substrate while maintaining fluid communication between the vias and the air space.

Abstract: A method and apparatus for providing a ball grid array assembly formed from interlocking ball grid array packages is disclosed. Each of the ball grid array packages has interlocking edge features for mechanical connection, whereby joining the plurality of ball grid array packages via the interlocking edge features forms the interlocking ball grid array assembly. The interlocking ball grid array assembly may then be mounted on a PC board as a single unit.

Abstract: A programmable substrate and a method of making a programmable substrate for use with array-type packages, including Ball Grid Arrays(BGA), Pin Grid Arrays (PGA) and Column Grid Arrays (CGA) includes a nonconductive programmable substrate with a cavity in the top of the substrate. The cavity is sized to receive an integrated circuit (IC) die. An array of electrically conductive vias pass through the substrate. A plurality of electrical traces are formed on the top of the substrate. The traces extend radially from an edge of the die cavity to the periphery of the substrate so as to pass between and near the vias. Each trace is electrically connected to a pad of the IC die by a wire bond. Each via is connected on a bottom surface of the substrate to a solder ball, pin, or other means for electrically and mechanically attaching the substrate to a printed circuit board. The traces are programmably connected to a selected via, e.g.

Abstract: A molded tape ball grid array package includes a molding compound and a tape substrate having a top surface for mounting a die thereon, a bottom surface for attaching solder balls, and vias for forming connections between the solder balls and the die wherein the molding compound surrounds the die and the tape substrate.

Abstract: Provided is an interposer tape which provides electrical communication between a die and a packaging substrate. The dimensions of the interposer tape may vary to accommodate a variety of die sizes for the same packaging substrate. The interposer tape includes an array of traces. A first set of wire bonds is formed between the array of traces and the die. A second set of wire bonds is formed between the array of traces and the packaging substrate.

Abstract: According to the present invention, a method for creating a package for a semiconductor die, the package comprising a flexible tape, comprises the following steps. A support with an opening has a plurality of arms extending through at a portion of the opening. For example, for a square opening, there may be eight arms, two extending from each side of the opening. The arms preferably form a “z” shape or some other shape with a transverse component. The flexible tape is then attached to the ends of the arms within the opening such that the flexible tape is supported by the arms. A die is attached to the flexible tape, the die is preferably covered with a molding compound, and the die/flexible tape assembly is scribed from the support, thereby creating an individual package.

Abstract: Provided is an apparatus and method for modifying the manufacture of chip carrier bond pads to increase the quality and reliability of semiconductor packages and ball joints in particular. This is accomplished by minimizing the corrosion of the barrier metal layer on the functional bond pads during gold deposition with the use of sacrificial pads electrically connected with the functional bond pads. According to one embodiment of the invention, a semiconductor package has copper conductive pads on a substrate that are exposed through a dielectric. Both functional and sacrificial (nonfunctional) copper conductive pads are provided. A barrier metal layer composed of nickel is electrolessly plated onto these conductive pads, and a bond metal layer of gold is deposited onto the nickel using electroless, generally immersion, gold plating.

Abstract: A semiconductor package (100) includes a bondable aluminum heatspreader (130) made from anodized aluminum, thereby forming an anodization layer (132) on the surface of the heatspreader. Portions of the anodization layer are removed, e.g., by grinding, in order to provide an attachment area (124) to which a wire (122) or beam may be bonded in order to electrically connect the heatspreader to a desired voltage potential, such as a ground potential or a positive or negative potential. The heatspreader is thermally bonded to a semiconductor die (102) housed within the package. The anodized aluminum heatspreader thus not only removes and dissipates heat from the semiconductor die, but also functions as a voltage or ground plane within the semiconductor package.

Abstract: A package for an integrated circuit is disclosed. The package comprises two layers (a top layer and a bottom layer) of flexible tape, each of which has a top surface and a bottom surface, with metal traces on the top surface. A die is mounted on top of the two layers and wire bonds connect bond pads on the die to metal traces on each of the two flexible tapes. The metal traces are routed along the top surfaces of the flexible tapes and are coupled to solder balls through holes in the tapes. These solder balls are mounted along the bottom of the package and serve as the electrical interface to a printed circuit board. Additional holes in the bottom layer tape allow solder balls to extend through the bottom layer tape so that they may be electrically coupled to traces on the top layer tape.