Abstract: A high density integrated test probe and method of fabrication is described. A group of wires are ball bonded to contact locations on the surface of a fan out substrate. The wires are sheared off leaving a stub, the end of which is flattened by an anvil. Before flattening a sheet of material having a group of holes is arranged for alignment with the group of stubs is disposed over the stubs. The sheet of material supports the enlarged tip. The substrate with stubs form a probe which is moved into engagement with contact locations on a work piece such as a drip or packaging substrate.

Abstract: A plated test probe structure for testing electrical connections to integrated circuits (IC) devices with solder bumped interconnection pads that are an integral part of the fan-out wiring on the test substrate, or other printed wiring device.

Abstract: Probes for electronic devices are described. The probe is formed by ball bonding a plurality of wires to contact locations on a fan out substrate surface. The wires are cut off leaving stubs. A patterned polymer sheet having electrical conductor patterns therein is disposed over the stubs which extend through holes in the sheet. The ends of the wires are flattened to remit the polymer sheet in place. The wire is connected to an electrical conductor on the polymer sheet which is converted to a contact pad on the polymer sheet. A second wire is ball bonded to the pad on the polymer sheet and cut to leave a second stub. The polymer sheet is laser cut so that each second stub is free to move independently of the other second studs. The ends of the second stubs are disposed against contact locations of an electronic device, such as an FC chip, to test the electronic device.

Abstract: A method is described having the steps of providing a surface having a plurality of wire bondable locations, wire bonding a wire to each of the wire bondable locations using a wire capillary tool; controlling the position of the capillary tool with respect to the substrate; after forming a wire bond of the wire to the wire bondable location moving the capillary tool relative to the surface as the capillary tool is moved away from the surface to form a wire having a predetermined shape.

Abstract: In the invention a compliant interposer is provided that accommodates variations in contact height, contact location, and contact materials. The interposer is in direct contact in the interface between the contact surface of the IC under test and the fan out wiring surface of the test equipment and which carries interconnection ability that is compliant with respect to the interfaces. The interposer has structurally parallel contacting layers that are compressively held apart at a separation distance by a fame member that in turn has areas in which interconnect members can move in accommodating spatial variations in the IC and fan out contacts in the interface. Each layer of the interposer, that is to be in contact with the IC contacts and with the fan out contacts has comparable a pattern of holes for each end region of each interconnect conductor members.

Abstract: Probes for electronic devices are described. The probe is formed by ball bonding a plurality of wires to contact locations on a fan out substrate surface. The wires are cut off leaving stubs. A patterned polymer sheet having electrical conductor patterns therein is disposed over the stubs which extend through holes in the sheet. The ends of the wires are flattened to remit the polymer sheet in place. The wire is connected to an electrical conductor on the polymer sheet which is converted to a contact pad on the polymer sheet. A second wire is ball bonded to the pad on the polymer sheet and cut to leave a second stub. The polymer sheet is laser cut so that each second stub is free to move independently of the other second studs. The ends of the second stubs are disposed against contact locations of an electronic device, such as an FC chip, to test the electronic device.

Abstract: Probes for electronic devices are described. The probe is formed by ball bonding a plurality of wires to contact locations on a fan out substrate surface. The wires are cut off leaving stubs. A patterned polymer sheet having electrical conductor patterns therein is disposed over the stubs which extend through holes in the sheet. The ends of the wires are flattened to remit the polymer sheet in place. The wire is connected to an electrical conductor on the polymer sheet which is converted to a contact pad on the polymer sheet. A second wire is ball bonded to the pad on the polymer sheet and cut to leave a second stub. The polymer sheet is laser cut so that each second stub is free to move independently of the other second studs. The ends of the second stubs are disposed against contact locations of an electronic device, such as an FC chip, to test the electronic device.

Abstract: A method is described having the steps of providing a surface having a plurality of wire bondable locations; wire bonding a wire to each of the wire bondable locations using a wire capillary tool; controlling the position of the capillary tool with respect to the substrate; after forming a wire bond of the wire to the wire bondable location moving the capillary tool relative to the surface as the capillary tool is moved away from the surface to form a wire having a predetermined shape.

Abstract: A method is described having the steps of providing a surface having a plurality of wire bondable locations; wire bonding a wire to each of the wire bondable locations using a wire capillary tool; controlling the position of the capillary tool with respect to the substrate; after forming a wire bond of the wire to the wire bondable location moving the capillary tool relative to the surface as the capillary tool is moved away from the surface to form a wire having a predetermined shape.

Abstract: The present invention is directed to a structure comprising a substrate having a surface; a plurality of elongated electrical conductors extending away from the surface; each of said elongated electrical conductors having a first end affixed to the surface and a second end projecting away from the surface; there being a plurality of second ends; and a means for positioning and maintaining the plurality of the second ends in substantially fixed positions with respect to each other. The structure is useful as a probe for testing and burning in integrated circuit chips at the wafer level.

Abstract: A method is described having the steps of providing a surface having a plurality of wire bondable locations; wire bonding a wire to each of the wire bondable locations using a wire capillary tool; controlling the position of the capillary tool with respect to the substrate; after forming a wire bond of the wire to the wire bondable location moving the capillary tool relative to the surface as the capillary tool is moved away from the surface to form a wire having a predetermined shape.

Abstract: The present invention is directed to a structure comprising a substrate having a surface; a plurality of elongated electrical conductors extending away from the surface; each of said elongated electrical conductors having a first end affixed to the surface and a second end projecting away from the surface; there being a plurality of second ends; and a means for maintaining the plurality of the second ends in substantially fixed positions with respect to each other. The structure is useful as a probe for testing and burning in integrated circuit chips at the wafer level.

Abstract: Method for repairing, reworking or replacing damaged probes that are formed using a flying lead wire bonding process used for testing integrated circuit devices and other electronic devices, with the same column and row spacing as the original probes and using the same height as the original probes.

Abstract: A probe structure for probing an electronic device.

Abstract: Method for repairing, reworking or replacing damaged probes that are formed using a flying lead wire bonding process used for testing integrated circuit devices and other electronic devices, with the same column and row spacing as the original probes and using the same height as the original probes.

Abstract: The present invention is directed to structures having a plurality of discrete insulated elongated electrical conductors projecting from a support surface which are useful as probes for testing of electrical interconnections to electronic devices, such as integrated circuit devices and other electronic components and particularly for testing of integrated circuit devices with rigid interconnection pads and multi-chip module packages with high density interconnection pads and the apparatus for use thereof and to methods of fabrication thereof. Coaxial probe structures are fabricated by the methods described providing a high density coaxial probe.

Abstract: The present invention is directed to a structure comprising a substrate having a surface; a plurality of elongated electrical conductors extending away from the surface; each of said elongated electrical conductors having a first end affixed to the surface and a second end projecting away from the surface; there being a plurality of second ends; and a means for maintaining the plurality of the second ends in substantially fixed positions with respect to each other.

Abstract: The present invention is directed to structures having a plurality of discrete insulated elongated electrical conductors projecting from a support surface which are useful as probes for testing of electrical interconnections to electronic devices and other electronic components and particularly for testing of integrated circuit devices with rigid interconnection pads and multi-chip module packages with high density interconnection pads and the apparatus for use thereof and to methods of fabrication thereof. Coaxial probe structures are fabricated by the methods described providing a high density coaxial probe.

Abstract: The present invention is directed to structures having a plurality of discrete insulated elongated electrical conductors projecting from a support surface which are useful as probes for testing of electrical interconnections to electronic devices, such as integrated circuit devices and other electronic components and particularly for testing of integrated circuit devices with rigid interconnection pads and multi-chip module packages with high density interconnection pads and the apparatus for use thereof and to methods of fabrication thereof. Coaxial probe structures are fabricated by the methods described providing a high density coaxial probe.

Abstract: A terminator assembly for a twinax wire. According to this embodiment, a PCB is provided which receives the twinax wire and provides a positive connection between a grounding bar of the PCB and the drain wide of the twinax pair. The drain wire is extended in an orthogonal direction to the twinax pair, and is engaged using an interference fit with the grounding bar. The grounding bar assembly also provides improved shielding for the twinax pair, where the integral shielding of the twinax wire has been removed to provide the connection. In an alternate embodiment, the terminating end of the twinax wire itself is encased in a termination clip. This clip provides shielding for the twinax pair, while electrically connecting with the twinax drain wire. The twinax wire, with the terminating clip, can then be easily attached to a connector PCB adapted to receive the terminator clip.