Abstract: A semiconductor device has a semiconductor die with a plurality of bumps formed over the die. A substrate has a plurality of conductive traces formed on the substrate. Each trace has an interconnect site for mating to the bumps. The interconnect sites have parallel edges along a length of the conductive traces under the bumps from a plan view for increasing escape routing density. The bumps have a noncollapsible portion for attaching to a contact pad on the die and fusible portion for attaching to the interconnect site. The fusible portion melts at a temperature which avoids damage to the substrate during reflow. The noncollapsible portion includes lead solder, and fusible portion includes eutectic solder. The interconnect sites have a width which is less than 1.2 times a width of the conductive trace. Alternatively, the interconnect sites have a width which is less than one-half a diameter of the bump.

Abstract: A semiconductor device has a semiconductor die with die bump pads and substrate with trace lines having integrated bump pads. A solder mask patch is formed interstitially between the die bump pads or integrated bump pads. The solder mask patch contains non-wettable material. Conductive bump material is deposited over the integrated bump pads or die bump pads. The semiconductor die is mounted over the substrate so that the conductive bump material is disposed between the die bump pads and integrated bump pads. The bump material is reflowed without a solder mask around the integrated bump pads to form an interconnect between the semiconductor die and substrate. The solder mask patch confines the conductive bump material within a footprint of the die bump pads or integrated bump pads during reflow. The interconnect can have a non-fusible base and fusible cap.

Abstract: A semiconductor device has a plurality of first semiconductor die with an encapsulant deposited over a first surface of the first semiconductor die and around the first semiconductor die. An insulating layer is formed over the encapsulant and over a second surface of the first semiconductor die opposite the first surface. The insulating layer includes openings over the first semiconductor die. A first conductive layer is formed over the first semiconductor die within the openings. A second conductive layer is formed over the first conductive layer to form vertical conductive vias. A second semiconductor die is disposed over the first semiconductor die and electrically connected to the first conductive layer. A bump is formed over the second conductive layer outside a footprint of the first semiconductor die. The second semiconductor die is disposed over an active surface or a back surface of the first semiconductor die.

Abstract: A semiconductor device has a semiconductor die with bond pads formed on a surface of the semiconductor die. A UBM is formed over the bond pads of the semiconductor die. A fusible layer is formed over the UBM. The fusible layer can be tin or tin alloy. A substrate has bond pads formed on a surface of the substrate. A plurality of stud bumps containing non-fusible material is formed over the bond pads on the substrate. Each stud bump includes a wire having a first end attached to the bond pad of the substrate and second end of uniform height electrically connected to the bond pad of the semiconductor die by reflowing the fusible layer or applying thermal compression bonding. An underfill material is deposited between the semiconductor die and substrate. An encapsulant is deposited over the semiconductor die and substrate.

Abstract: A semiconductor package having an embedded die and solid vertical interconnections, such as stud bump interconnections, for increased integration in the direction of the z-axis (i.e., in a direction normal to the circuit side of the die). The semiconductor package can include a die mounted in a face-up configuration (similar to a wire bond package) or in a face-down or flip chip configuration.

Abstract: A semiconductor device has a semiconductor die with die bump pads and substrate with trace lines having integrated bump pads. A solder mask patch is formed interstitially between the die bump pads or integrated bump pads. The solder mask patch contains non-wettable material. Conductive bump material is deposited over the integrated bump pads or die bump pads. The semiconductor die is mounted over the substrate so that the conductive bump material is disposed between the die bump pads and integrated bump pads. The bump material is reflowed without a solder mask around the integrated bump pads to form an interconnect between the semiconductor die and substrate. The solder mask patch confines the conductive bump material within a footprint of the die bump pads or integrated bump pads during reflow. The interconnect can have a non-fusible base and fusible cap.

Abstract: A semiconductor device has a semiconductor wafer with a plurality of semiconductor die. Contact pads are formed on a surface of the semiconductor die. The semiconductor die are separated to form a peripheral region around the semiconductor die. An encapsulant or insulating material is deposited in the peripheral region around the semiconductor die. An interconnect structure is formed over the semiconductor die and insulating material. The interconnect structure has an I/O density less than an I/O density of the contact pads on the semiconductor die. A substrate has an I/O density consistent with the I/O density of the interconnect structure. The semiconductor die is mounted to the substrate with the interconnect structure electrically connecting the contact pads of the semiconductor die to the first conductive layer of the substrate. A plurality of semiconductor die each with the interconnect structure can be mounted over the substrate.

Abstract: A solder bump confinement system is provided includes a substrate; a contact material patterned on the substrate; an inner passivation layer deposited over the contact material and the substrate; an under bump material pad over the contact material; an under bump material defining layer, having a bump opening contained therein, directly on the under bump material pad in which the under bump material defining layer has a thickness in the range of 200 Angstrom to 1500 Angstrom; and a system interconnect formed over the contact material and coupled to the under bump material defining layer and the under bump material pad through the bump opening.

Abstract: An integrated circuit package system is provided forming a first I/O cell having a first circuitry area and a first bond pad with the first circuitry area partitioned along a cell length and on opposing perimeter segment of the first bond pad, forming an I/O ring having the first I/O cell, forming an integrated circuit die having the I/O ring, and connecting an external interconnect and the first bond pad.

Abstract: A method for forming metallurgical interconnections and polymer adhesion of a flip chip to a substrate includes providing a chip having a set of bumps formed on a bump side thereof and a substrate having a set of interconnect points on a metallization thereon, providing a measured quantity of a polymer adhesive in a middle region of the chip on the bump side, aligning the chip with the substrate so that the set of bumps aligns with the set of interconnect points, pressing the chip and the substrate toward one another so that a portion of the polymer adhesive contacts the substrate and the bumps contact the interconnect points, and heating the bumps to a temperature sufficiently high to form a metallurgical connection between the bumps and the interconnect points.

Abstract: A semiconductor die has a conductive layer including a plurality of trace lines formed over a carrier. The conductive layer includes a plurality of contact pads electrically continuous with the trace lines. A semiconductor die has a plurality of contact pads and bumps formed over the contact pads. A plurality of conductive pillars can be formed over the contact pads of the semiconductor die. The bumps are formed over the conductive pillars. The semiconductor die is mounted to the conductive layer with the bumps directly bonded to an end portion of the trace lines to provide a fine pitch interconnect. An encapsulant is deposited over the semiconductor die and conductive layer. The conductive layer contains wettable material to reduce die shifting during encapsulation. The carrier is removed. An interconnect structure is formed over the encapsulant and semiconductor die. An insulating layer can be formed over the conductive layer.

Abstract: An integrated circuit package system and method of manufacture therefor includes: forming an area array substrate; mounting surface conductors on the area array substrate; forming a molded package body on the area array substrate and the surface conductors; providing a step in the molded package body; and exposing a surface conductor by the step.

Abstract: A semiconductor device has a semiconductor die with a plurality of tapered bumps formed over a surface of the semiconductor die. The tapered bumps can have a non-collapsible portion and collapsible portion. A plurality of conductive traces is formed over a substrate with interconnect sites. A masking layer is formed over the substrate with openings over the conductive traces. The tapered bumps are bonded to the interconnect sites so that the tapered bumps contact the mask layer and conductive traces to form a void within the opening of the mask layer over the substrate. The substrate can be non-wettable to aid with forming the void in the opening of the masking layer. The void provides thermally induced stress relief. Alternatively, the masking layer is sufficiently thin to avoid the tapered interconnect structures contacting the mask layer. An encapsulant or underfill material is deposited between the semiconductor die and substrate.

Abstract: A solder mask for flip chip interconnection has a common opening that spans a plurality of circuit elements. The solder mask allows confinement of the solder during the re-melt stage of interconnection, yet it is within common design rules for solder mask patterning. Also, a substrate for flip chip interconnection includes a substrate having the common opening that spans a plurality of circuit elements. Also, a flip chip package includes a substrate having a common opening that spans a plurality of circuit elements.

Abstract: A flip chip interconnect is made by mating the interconnect bump directly onto a lead, rather than onto a capture pad. Also, a flip chip package includes a die having solder bumps attached to interconnect pads in an active surface, and a substrate having electrically conductive traces in a die attach surface, in which the bumps are mated directly onto the traces. In some embodiments the interconnection is formed without employing a solder mask. In some methods a curable adhesive is dispensed either onto the bumps on the die or onto the traces on the substrate; the adhesive is partly cured during the mating process, and the partly cured adhesive serves to confine the molten solder during a reflow process.

Abstract: A semiconductor device has a semiconductor die with a plurality of bumps formed over the die. A substrate has a plurality of conductive traces formed on the substrate. Each trace has an interconnect site for mating to the bumps. The interconnect sites have parallel edges along a length of the conductive traces under the bumps from a plan view for increasing escape routing density. The bumps have a noncollapsible portion for attaching to a contact pad on the die and fusible portion for attaching to the interconnect site. The fusible portion melts at a temperature which avoids damage to the substrate during reflow. The noncollapsible portion includes lead solder, and fusible portion includes eutectic solder. The interconnect sites have a width which is less than 1.2 times a width of the conductive trace. Alternatively, the interconnect sites have a width which is less than one-half a diameter of the bump.

Abstract: A semiconductor device has a first substrate with a central region. A plurality of bumps is formed around a periphery of the central region of the first substrate. A first semiconductor die is mounted to the central region of the first substrate. A second semiconductor die is mounted to the first semiconductor die over the central region of the first substrate. A height of the first and second die is less than or equal to a height of the bumps. A second substrate has a thermal conduction channel. A surface of the second semiconductor die opposite the first die is mounted to the thermal conductive channel of the second substrate. A thermal interface layer is formed over the surface of the second die. The bumps are electrically connected to contact pads on the second substrate. A conductive plane is formed over a surface of the second substrate.

Abstract: A flip chip interconnect is made by mating the interconnect bump directly onto a lead, rather than onto a capture pad. Also, a flip chip package includes a die having solder bumps attached to interconnect pads in an active surface, and a substrate having electrically conductive traces in a die attach surface, in which the bumps are mated directly onto the traces. In some embodiments the interconnection is formed without employing a solder mask. In some methods a curable adhesive is dispensed either onto the bumps on the die or onto the traces on the substrate; the adhesive is partly cured during the mating process, and the partly cured adhesive serves to confine the molten solder during a reflow process.

Abstract: A semiconductor device has a semiconductor die mounted to a substrate with a plurality of composite interconnects formed between interconnect sites on the substrate and bump pads on the die. The interconnect sites are part of traces formed on the substrate. The interconnect site has a width between 1.0 and 1.2 times a width of the trace. The composite interconnect is tapered. The composite interconnects have a fusible portion connected to the interconnect site and non-fusible portion connected to the bump pad. The non-fusible portion can be gold, copper, nickel, lead solder, or lead-tin alloy. The fusible portion can be tin, lead-free alloy, tin-silver alloy, tin-silver-copper alloy, tin-silver-indium alloy, eutectic solder, or other tin alloys with silver, copper, or lead. An underfill material is deposited between the semiconductor die and substrate. A finish such as Cu-OSP can be formed over the substrate.

Abstract: A semiconductor device has a semiconductor die with a plurality of bumps formed over the die. A substrate has a plurality of conductive traces formed on the substrate. Each trace has an interconnect site for mating to the bumps. The interconnect sites have parallel edges along a length of the conductive traces under the bumps from a plan view for increasing escape routing density. The bumps have a noncollapsible portion for attaching to a contact pad on the die and fusible portion for attaching to the interconnect site. The fusible portion melts at a temperature which avoids damage to the substrate during reflow. The noncollapsible portion includes lead solder, and fusible portion includes eutectic solder. The interconnect sites have a width which is less than 1.2 times a width of the conductive trace. Alternatively, the interconnect sites have a width which is less than one-half a diameter of the bump.