Abstract: The invention relates to a tester apparatus of the kind including a portable supporting structure for removably holding and testing a substrate carrying a microelectronic circuit. An interface on the stationary structure is connected to the first interface when the portable structure is held by the stationary structure and is disconnected from the first interface when the portable supporting structure is removed from the stationary structure. An electrical tester is connected through the interfaces so that signals may be transmitted between the electrical tester and the microelectronic circuit to test the microelectronic circuit.

Abstract: The invention relates to a tester apparatus of the kind including a portable supporting structure for removably holding and testing a substrate carrying a microelectronic circuit. An interface on the stationary structure is connected to the first interface when the portable structure is held by the stationary structure and is disconnected from the first interface when the portable supporting structure is removed from the stationary structure. An electrical tester is connected through the interfaces so that signals may be transmitted between the electrical tester and the microelectronic circuit to test the microelectronic circuit.

Abstract: A cartridge, including a cartridge frame, formations on the cartridge frame for mounting the cartridge frame in a fixed position to an apparatus frame, a contactor support structure, a contactor interface on the contactor support structure, a plurality of terminals, held by the contactor support structure, for contacting contacts on a device, and a plurality of conductors, held by the contactor support structure, connecting the interface to the terminals.

Abstract: The invention relates to a tester apparatus of the kind including a portable supporting structure for removably holding and testing a substrate carrying a microelectronic circuit. An interface on the stationary structure is connected to the first interface when the portable structure is held by the stationary structure and is disconnected from the first interface when the portable supporting structure is removed from the stationary structure. An electrical tester is connected through the interfaces so that signals may be transmitted between the electrical tester and the microelectronic circuit to test the microelectronic circuit.

Abstract: A microelectronic spring contact for making electrical contact between a device and a mating substrate and method of making the same are disclosed. The spring contact has a compliant pad adhered to a substrate of the device and spaced apart from a terminal of the device. The compliant pad has a base adhered to the substrate, and side surfaces extending away from the substrate and tapering to a smaller end area distal from the substrate. A trace extends from the terminal of the device in a coil pattern over the compliant pad to its end area, forming a helix. At least a portion of the compliant pad end area is covered by the trace, and a portion of the trace that is over the compliant pad is supported by the compliant pad. In an alternative embodiment, the pad is removed to leave a freestanding helical contact.

Abstract: A system for testing integrated circuits is described. A contactor board of the system has pins with ends that contact terminals on a power and signal distribution board. Opposing ends of the pins make contact with die terminals on an unsingulated wafer. The distribution board also carries a plurality of capacitors, at least one capacitor corresponding to every die on the unsingulated wafer. Each capacitor may include two substantially flat planar capacitor conductors and a dielectric layer between the capacitor conductors. Alternatively, the capacitors may be discrete components mounted to and standing above the distribution board, in which case corresponding capacitor openings are formed in the contactor substrate to accommodate the capacitors when the distribution board and the contactor board are brought together. A plurality of fuses made of a polymer material are also provided.

Abstract: A microelectronic spring contact for making electrical contact between a device and a mating substrate and method of making the same are disclosed. The spring contact has a compliant pad adhered to a substrate of the device and spaced apart from a terminal of the device. The compliant pad has a base adhered to the substrate, and side surfaces extending away from the substrate and tapering to a smaller end area distal from the substrate. A trace extends from the terminal of the device in a coil pattern over the compliant pad to its end area, forming a helix. At least a portion of the compliant pad end area is covered by the trace, and a portion of the trace that is over the compliant pad is supported by the compliant pad. In an alternative embodiment, the pad is removed to leave a freestanding helical contact.

Abstract: A microelectronic spring contact for making electrical contact between a device and a mating substrate and method of making the same are disclosed. The spring contact has a compliant pad adhered to a substrate of the device and spaced apart from a terminal of the device. The compliant pad has a base adhered to the substrate, and side surfaces extending away from the substrate and tapering to a smaller end area distal from the substrate. A trace extends from the terminal of the device in a coil pattern over the compliant pad to its end area, forming a helix. At least a portion of the compliant pad end area is covered by the trace, and a portion of the trace that is over the compliant pad is supported by the compliant pad. In an alternative embodiment, the pad is removed to leave a freestanding helical contact.

Abstract: A method of electrically coupling a first substrate (12) and a second substrate (30) includes forming a conductive bump (20) on the first substrate (12) by electroless plating a metal and nonconductive particles (26) together. The first substrate (12) and the second substrate (30) are bonded with a nonconductive polymer (40) so that the conductive bump (20) and a conductive pad (32) of the second substrate 30) are electrically coupled.

Abstract: A method of manufacturing components includes providing a substrate (110, 531, 631, 700) having a first coefficient of thermal expansion (CTE), having a first surface (111), and supporting a first plurality of interconnects located over the first surface in a first predetermined pattern. The method also includes providing another substrate (190) having a second CTE, having a second surface (195), and supporting a second plurality of interconnects located over the second surface in a second predetermined pattern. The method further includes assembling together the two substrates at a first temperature outside of a temperature range of approximately 25 to 30° C.

Abstract: A semiconductor wafer contact system includes a sealed bladder (32) containing incompressible material. The sealed bladder (32) presses against a flexible circuit layer (28) including an array of electrical contacts (30). The bladder (32) forces the array of electrical contacts (30) against a corresponding array of device electrical contacts (12) on die (11) of a semiconductor wafer (10). The bladder (32) adapts in shape to compensate for die level and wafer level irregularities in contact height and non-parallelism. Additionally, bladder (32) ensures a constant force between membrane contacts (30) and die contacts (12), across the entire wafer (10).

Abstract: A semiconductor wafer contact system includes a base substrate (13) which has an array of raised supports (18). The array of raised supports (18) are distributed in a pattern corresponding to the pattern of electrical contacts (12) on the semiconductor wafer (10), to be contacted. In between the base substrate (13) and the wafer to be contacted (10) is a flexible circuit layer (14) including an array of electrical contacts (15) having the same pattern as the contacts (12) of the wafer and the raised supports (18). The raised supports (18) provide focused and localized force, pressing the membrane test contacts (15) against the wafer electrical contacts (12).