Abstract: A surface mount electrical interconnect is disclosed that provides an interface between a PCB and solder balls of a BGA device. The electrical interconnect includes a socket substrate and a plurality of electrically conductive contact members. The socket substrate has a first layer with a plurality of openings configured to receive solder balls of the BGA device and has a second layer with a plurality of slots defined therethrough that correspond to the plurality of openings. The contact members may be disposed in the openings in the first layer and through the plurality of slots of the second layer of the socket substrate. The contact members can be configured to engage a top portion, a center diameter, and a lower portion of the solder ball of the BGA device. Each contact member electrically couples a solder ball on the BGA device to the PCB.

Abstract: A backplane connector including a substrate and a backplane connector set attached to the substrate. The backplane connector set includes a plurality of interconnect elements each having a conductive trace, a first contact member, and a second contact members matched to the first contact member. The first and second contact members extend beyond perimeter edges of the substrate. A plurality of conductive tie bars retain the interconnect elements in a fixed relationship prior to attachment to the substrate. Additive printing processes can be used to form the conductive traces.

Abstract: A semiconductor device packaged adapter for electrically coupling contacts on a first circuit member to contacts on a second circuit member. The adapter typically includes first and second substrates, each with arrays of terminals. Proximal ends of the first terminals on the first substrate are arranged to be soldered to the contacts on the first circuit member and proximal ends of the) second terminals on the second substrate are arranged to be soldered to the contacts on the second circuit member. Complementary engaging structures located on distal ends of the first and second terminals engage to electrically and mechanically couple the first circuit member to the second circuit member.

Abstract: A socket housing and method of making the socket housing. A plurality of dielectric layers are printed with a plurality of recesses on a substrate. The dielectric layers include at least two different dielectric materials. A sacrificial material is printed ted in the recesses. The assembly is removed from the substrate and the sacrificial material is removed from the recesses. At least one contact member is located in a plurality of the recesses. Distal ends of the contact members are adapted to electrically couple with circuit members.

Abstract: Diagnostic tools for testing integrated circuit (IC) devices, and a method of making the same. The first diagnostic tool includes a first compliant printed circuit with a plurality of contact pads configured to form an electrical interconnect at a first interface between proximal ends of contact members in the socket and contact pads on a printed circuit board (PCB). A plurality of printed conductive traces electrically couple to a plurality of the contact pads on the first compliant printed circuit. A plurality of electrical devices are printed on the first compliant printed circuit at a location external to the first interface. The electrical devices are electrically coupled to the conductive traces and programmed to provide one or more of continuity testing at the first interface or functionality of the IC devices. A second diagnostic tool includes a second compliant printed circuit electrically coupled to a surrogate IC device.

Abstract: A surface mount electrical interconnect adapted to provide an interface between solder balls on a BGA device and a PCB. A socket substrate is provided with a first surface, a second surface, and a plurality of openings sized and configured to receive the solder balls on the BGA device. A plurality of electrically conductive contact tabs are attached to the socket substrate so that contact tips on the contact tabs extend into the openings. The contact tips electrically couple with the BGA device when the solder balls are positioned in the openings. Vias electrically couple the contact tabs to contact pads located proximate the second surface of the socket substrate. Solder balls are bonded to the contact pads to electrically and mechanically couple the electrical interconnect to the PCB.

Abstract: An electrical interconnect for providing a temporary interconnect between terminals on an IC device and contact pads on a printed circuit board (PCB). The electrical interconnect includes a substrate with a first surface having a plurality of openings arranged to correspond to the terminals on the IC device. A compliant material is located in the openings. A plurality of conductive traces extend along the first surface of the substrate and onto the compliant material. The compliant material provides a biasing force that resists flexure of the conductive traces into the openings. Conductive structures are electrically coupled to the conductive traces over the openings. The conductive structures are adapted to enhance electrical coupling with the terminals on the IC device. Vias electrically extending through the substrate couple the conductive traces to PCB terminals located proximate a second surface of the substrate.

Abstract: An electrical interconnect providing an interconnect between contacts on an IC device and contact pads on a printed circuit board (PCB). The electrical interconnect includes a substrate with a plurality of through holes extending from a first surface to a second surface. A resilient material is located in the through holes. The resilient material includes an opening extending from the first surface to the second surface. A plurality of discrete, free-flowing conductive nano-particles are located in the openings of the resilient material. The conductive particles are substantially free of non-conductive materials. A plurality of first contact members are located in the through holes adjacent the first surface and a plurality of second contact members are located in the through holes adjacent the second surface. The first and second contact members are electrically coupled to the nano-particles.

Abstract: A probe assembly that acts as a temporary interconnect between terminals on an IC device and a test station. The probe assembly includes a plurality of stud bumps arranged on a first surface of a substrate in a configuration corresponding to the terminal on the IC device. The stud bumps include a shape adapted to temporarily couple with the terminals on the IC device. A plurality of conductive traces on the substrate electrically couple the stud bumps with the test station.

Abstract: An electrical interconnect including a first circuitry layer with a first surface and a second surface. At least a first dielectric layer is printed on the first surface of the first circuitry layer to include a plurality of first recesses. A conductive material is deposited in a plurality of the first recesses to form a plurality of first conductive pillars electrically coupled to, and extending generally perpendicular to, the first circuitry layer. At least a second dielectric layer is printed on the first dielectric layer to include a plurality of second recesses generally aligned with a plurality of the first conductive pillars. A conductive material is deposited in a plurality of the second recesses to form a plurality of second conductive pillars electrically coupled to, and extending parallel the first conductive pillars.

Abstract: An area array integrated circuit (IC) package for an IC device. The IC package includes a first substrate with conductive traces electrically coupled to the IC device. An interconnect assembly having a first surface is mechanically coupled to the first substrate. The interconnect assembly includes a plurality of contact members electrically coupled to the conductive traces on the first substrate. A second substrate is mechanically coupled to a second surface of the interconnect assembly so that the first substrate, the interconnect assembly, and the second substrate substantially surround the IC device. The second substrate includes conductive traces that are electrically coupled to the contact members in the interconnect assembly.

Abstract: A surface mount electrical interconnect to provide an interface between a PCB and contacts on an integrated circuit device. The electrical interconnect includes a substrate with a plurality of recesses arranged along a first surface to correspond to the contacts on the integrated circuit device. Contact members are located in a plurality of the recess. The contact members include contact tips adapted to electrically couple with the contacts on the integrated circuit device. An electrical interface including at least one circuit trace electrically couples the contact member to metalized pads located along a second surface of the substrate at a location offset from a corresponding contact member. A solder ball is attached to a plurality of the metalized pads.

Abstract: A probe assembly that acts as a temporary interconnect between terminals on a circuit member and a test station. The probe assembly can include a base layer of a dielectric material printed onto a surface of a fixture. The surface of the fixture can have a plurality of cavities. A plurality of discrete contact members can be formed in the plurality of cavities in the fixture and coupled to the base layer. A plurality of conductive traces can be printed onto an exposed surface of the base layer and electrically coupled with proximal ends of one or more of the discrete contact members. A compliant layer can be deposited over the conductive traces and the proximal ends of the contact members. A protective layer can be deposited on the compliant layer such that when the probe assembly is removed from the fixture the distal ends of the contact members contact terminals on the circuit member and the conductive traces electrically couple the circuit member to a test station.

Abstract: A semiconductor package with simulated wirebonds. A substrate is provided with a plurality of first pads on a first surface and a plurality of second pads on a second surface. Each of the first pads are electrically coupled to one or more of the second pads. At least one semiconductor device is located proximate the first surface of a substrate. The simulated wirebonds include at least a first dielectric layer selectively printed to create a plurality of recesses, and a conductive material located in the recesses to form first and second contact pads, and electrical traces electrically coupling the first and second contact pads. The first contact pads are electrically coupled to terminals on the semiconductor device and the second contact pads are electrically coupled to the first pads on the first surface of the substrate.

Abstract: An integrated circuit (IC) package for an IC device, and a method of making the same. The IC package includes an interconnect assembly with at least one printed compliant layer, a plurality of first contact members located along a first major surface, a plurality of second contact members located along a second major surface, and a plurality of printed conductive traces electrically coupling a plurality of the first and second contact members. The compliant layer is positioned to bias at least the first contact members against terminals on the IC device. Packaging substantially surrounds the IC device and the interconnect assembly. The second contact members are accessible from outside the packaging.

Abstract: Diagnostic tools for testing wafer-level IC devices, and a method of making the same. The first diagnostic tool can include a first compliant printed circuit with a plurality of contact pads configured to form an electrical interconnect at a first interface between distal ends of probe members in the wafer probe and contact pads on a wafer-level IC device. A plurality of printed conductive traces electrically couple to a plurality of the contact pads on the first compliant printed circuit. A plurality of electrical devices are printed on the first compliant printed circuit at a location away from the first interface. The electrical devices are electrically coupled to the conductive traces and are configured to provide one or more of continuity testing or functionality of the wafer-level IC devices. A second diagnostic tool includes a second compliant printed circuit electrically coupled to a dedicated IC testing device.

Abstract: A compliant printed circuit semiconductor tester interface that provides a temporary interconnect between terminals on integrated circuit (IC) devices being tested. The compliant printed circuit semiconductor tester interface includes at least one dielectric layer printed with recesses corresponding to a target circuit geometry. A conductive material is deposited in at least a portion of the recesses comprising a circuit geometry and a plurality of first contact pads accessible along a first surface of the compliant printed circuit. At least one dielectric covering layer is preferably applied over the circuit geometry. A plurality of openings in the dielectric covering layer are provided to permit electrical coupling of terminals on the IC device and the first contact pads. Testing electronics that to test electrical functions of the IC device are electrically coupled to the circuit geometry.

Abstract: A wafer-level package for semiconductor devices and a method for making the package. At least one dielectric layer is selectively printed on at least a portion of the semiconductor devices creating first recesses aligned with a plurality of electrical terminals on the semiconductor devices. A conductive material is printed in the first recesses to form contact members on the semiconductor devices. At least one dielectric layer is selectively printed to create a plurality of second recesses corresponding to a target circuit geometry. A conductive material is printed in at least a portion of the second recesses to create a circuit geometry. The circuit geometry includes a plurality of exposed terminals adapted to electrically couple to another circuit member. The wafer is diced to provide a plurality of discrete packaged semiconductor devices.

Abstract: An interconnect assembly including a substrate with a plurality of through holes extending from a first surface to a second surface. A plurality of discrete contact member are located in the plurality of through holes. The contact members include proximal ends that are accessible from the second surface, distal ends extending above the first surface, and intermediate portions engaged with an engagement region of the substrate located between the first surface and the recesses. Retention members are coupled with at least a portion of the proximal ends to retain the contact members in the through holes. The retention members can be made from a variety of materials with different levels of conductivity, ranging from highly conductive to non-conductive.

Abstract: A socket assembly that forms a solderless electrical interconnection between terminals on a singulated integrated circuit device and another circuit member. The socket housing has an opening adapted to receive the singulated integrated circuit device. The compliant printed circuit is positioned relative to the socket housing to electrically couple with the terminals on a singulated integrated circuit device located in the opening. The compliant printed circuit includes a dielectric base layer printed onto a surface of a fixture, while leaving cavities in the surface of the fixture exposed. A plurality of contact members are formed in the plurality of cavities in the fixture and coupled to the dielectric base layer. The contact members are exposed wherein the compliant printed circuit is removed from the fixture. At least one dielectric layer with recesses corresponding to a target circuit geometry is printed on the dielectric base layer.