Abstract: Techniques for performing wafer-level burn-in and test of semiconductor devices include a test substrate having active electronic components such as ASICs mounted to an interconnection substrate or incorporated therein, metallic spring contact elements effecting interconnections between the ASICs and a plurality of devices-under-test (DUTs) on a wafer-under-test (WUT), all disposed in a vacuum vessel so that the ASICs can be operated at temperatures independent from and significantly lower than the burn-in temperature of the DUTs. The spring contact elements may be mounted to either the DUTs or to the ASICs, and may fan out to relax tolerance constraints on aligning and interconnecting the ASICs and the DUTs.

Abstract: A transmission line includes a signal conductor and at least one varactor diode capacitively coupled to the signal conductor. The transmission line's signal path delay is a function of its shunt capacitance, and the varactor's capacitance forms a part of the transmission line's shunt capacitance. The transmission line's signal path delay is adjusted by adjusting a control voltage across the varactor diode thereby to adjust the varactor diode's capacitance.

Abstract: A method is disclosed that can be used to interconnect an integrated circuit (IC) multiple die assembly to conductors on a substrate such that signals can be conveyed between the dies and the conductors on the substrate. The multiple die assembly can include a first IC die and at least one secondary IC die, which can be mounted on a surface of the first IC die. Signal paths can be provided between the first IC die and the secondary IC die. The method can include providing conductive contacts on the surface of the first IC die. Each such conductive contact can have a free end extending outward from the surface beyond the secondary IC die. The method can also include mounting the multiple die assembly on the substrate such that the free end of each contact is brought into contact with the conductors on the substrate. The secondary IC die can reside between the surface of the first IC die and the substrate, and the contacts can convey signals between the first IC die and the conductors on the substrate.

Abstract: Embodiments of resilient contact elements and methods for fabricating same are provided herein. In one embodiment, a resilient contact element for use in a probe card includes a lithographically formed resilient beam having a first end and an opposing second end; and a tip disposed proximate the first end of the beam and configured to break through an oxide layer of a surface of a device to be tested to establish a reliable electrical connection therewith; wherein at least a central portion of the beam has a continuous sloped profile defining, in a relaxed state, a height measured between the beam and a plane representing an upper surface of a device to be tested that is greater near the second end of the beam than near the first end of the beam.

Abstract: According to some embodiments, a method of determining a resistance of probes on a contactor device is disclosed. The contactor device can include a plurality of probes disposed to contact an electronic device to be tested. The method can include electrically connecting a pair of the probes to each other, and then forcing one of a voltage onto or a current through the pair of the probes. At a location on the contactor device, the other of a voltage across or a current through the pair of the probes can be sensed. A determination relating to a resistance of the probes can be determined from the values of the forced voltage or current and sensed other of the voltage or current.

Abstract: One or more testers wirelessly communicate with one or more test stations. The wireless communication may include transmission of test commands and/or test vectors to a test station, resulting in testing of one or more electronic devices at the test station. The wireless communication may also include transmission of test results to a tester. Messages may also be wirelessly exchanged.

Abstract: An electronic component is disclosed, having a plurality of microelectronic spring contacts mounted to a planar face of the component. Each of the microelectronic spring contacts has a contoured beam, which may be formed of an integral layer of resilient material deposited over a contoured sacrificial substrate, and comprises a base mounted to the planar face of the component, a beam connected to the base at a first end of the beam, and a tip positioned at a free end of the beam opposite to the base. The beam has an unsupported span between its free end and its base. The microelectronic spring contacts are advantageously formed by depositing a resilient material over a molded, sacrificial substrate. The spring contacts may be provided with various innovative contoured shapes. In various embodiments of the invention, the electronic component comprises a semiconductor die, a semiconductor wafer, a LGA socket, an interposer, or a test head assembly.

Abstract: Probes of a probe card assembly can be adjusted with respect to an element of the probe card assembly, which can be an element of the probe card assembly that facilitates mounting of the probe card assembly to a test apparatus. The probe card assembly can then be mounted in a test apparatus, and an orientation of the probe card assembly can be adjusted with respect to the test apparatus, such as a structural part of the test apparatus or a structural element attached to the test apparatus.

Abstract: Method and apparatus for testing semiconductor devices with autonomous expected value generation is described. Examples of the invention can relate to apparatus for interfacing a tester and a semiconductor device under test (DUT). An apparatus can include output processing logic configured to receive test result signals from the DUT responsive to testing by the tester, the output processing logic voting a logic value of a majority of the test result signals as a correct logic value; and memory configured to store indications of whether each of the test result signals has the correct logic value.

Abstract: A probe card assembly includes a first probe head having contact elements disposed on a respective surface for forming electrical contacts with corresponding terminals of corresponding electronic devices, a second probe head having contact elements disposed on a respective surface for forming electrical contacts with corresponding terminals of corresponding electronic devices, and a controlling mechanism coupled to the first and second probe heads for controlling movement of the first and second probe heads in a first direction substantially parallel to the respective surfaces more than in a second direction substantially normal to the respective surfaces.

Abstract: A wafer test assembly includes multiple probe head substrates arranged like tiles with connectors attached to one side and probes supported on the opposing side. In one embodiment, flexible cable connectors directly connect the connectors on the probe head tile to a test head, while in another embodiment the flexible cables connect the probe head tile to a PCB providing horizontal routing to test head connectors. In one embodiment, leveling pins provide a simplified support structure connecting to a retaining element attached to the tiles to provide for applying a push-pull leveling force. A test head connector interface frame enables rearrangement of connectors between the test head and the probe card to provide for both full wafer contact or partial wafer contact. The test head connectors are rearranged by being slidable on rails, or pluggable and unpluggable enabling movement over a range of positions.

Abstract: Systems and methods for depositing a plurality of droplets in a three-dimensional array are disclosed. The array can comprise a first type of droplets disposed to form a support structure and a second type of droplets forming a conductive seed layer on the support structure. A structure material can be electrodeposited onto the seed layer to create a three-dimensional structure.

Abstract: Double-sided interposer assemblies and methods for forming and using them. In one example of the invention, an interposer comprises a substrate having a first surface and a second surface opposite of said first surface, a first plurality of contact elements disposed on said first side of said substrate, and a second plurality of contact elements disposed on said second surface of said substrate, wherein said interposer connects electronic devices via said first and said second plurality of contact elements.

Abstract: A contactor device comprising a plurality of probes disposed to contact ones of the electronic devices can be electrically connected to a source of test signals. A switch can be activated electrically connecting a connection to the source of test signals to a selected one of a first group of electrically connected ones of the probes disposed to contact a first set of a plurality of the electronic devices or a second group of electrically connected ones of the probes disposed to contact a second set of a plurality of the electronic devices.

Abstract: The present invention discloses a method and system compensating for thermally induced motion of probe cards used in testing die on a wafer. A probe card incorporating temperature control devices to maintain a uniform temperature throughout the thickness of the probe card is disclosed. A probe card incorporating bi-material stiffening elements which respond to changes in temperature in such a way as to counteract thermally induced motion of the probe card is disclosed including rolling elements, slots and lubrication. Various means for allowing radial expansion of a probe card to prevent thermally induced motion of the probe card are also disclosed. A method for detecting thermally induced movement of the probe card and moving the wafer to compensate is also disclosed.

Abstract: An electronics module is assembled by demountably attaching integrated circuits to a module substrate. The module is then tested at a particular operating speed. If the module fails to operate correctly at the tested speed, the integrated circuit or circuits that caused the failure are removed and replaced with new integrated circuits, and the module is retested. Once it is determined that the module operates correctly at the tested speed, the module may be rated to operate at the tested speed and sold, or the module may be tested at a higher speed.

Abstract: Embodiments of reinforced resilient elements and methods for fabricating same are provided herein. In one embodiment, a reinforced resilient element includes a resilient element configured to electrically probe an unpackaged semiconductor device to be tested, the resilient element having a first end and an opposing second end; and a reinforcement member having a first end affixed to the resilient element at the first end thereof or at a point disposed between the first and the second ends of the resilient element, an opposing second end disposed in a direction towards the second end of the resilient element, and a resilient portion disposed between the first and second ends, wherein the resilient portion is not affixed to the resilient element.

Abstract: Embodiments of apparatus for thermally conditioning probe cards prior to use in a testing system are provided herein. In some embodiments, a probe card thermal conditioning system may include an enclosure configured to support a probe card and a heat transfer element disposed proximate a bottom of the enclosure for thermally conditioning the probe card prior to installation in a prober. The heat transfer element may be a heating and/or cooling element. A controller may be provided for controlling operation of the heat transfer element, optionally with temperature feedback. Multiple enclosures may be provided for independently conditioning multiple probe cards. The enclosure may be contained in a cart or may be part of shipping container for shipping a probe card. A fan may be provided for circulating air within the enclosure. The fan may facilitate providing a dry purge gas to prevent condensate from forming on the probe card.

Abstract: Resilient spring contact structures are manufactured by plating the contact structures on a reusable mandrel, as opposed to forming the contact structures on sacrificial layers that are later etched away. In one embodiment, the mandrel includes a form or mold area that is inserted through a plated through hole in a substrate. Plating is then performed to create the spring contact on the mold area of the mandrel as well as to attach the spring contact to the substrate. In a second embodiment, the mandrel includes a form that is initially plated to form the resilient contact structure and then attached to a region of a substrate without being inserted through the substrate. Attachment in the second embodiment can be achieved during the plating process used to form the spring contact, or by using a conductive adhesive or solder either before or after releasing the spring contact from the mandrel.

Abstract: A probe card assembly can comprise a probe head assembly and a wiring substrate. The probe head assembly can comprise a plurality of probes disposed to contact an electronic device disposed on a holder in a test housing. The wiring substrate can include an electrical interface to a test controller and a plurality of electrical wiring composing electrical paths between the electrical interface and ones of the probes, and the wiring substrate can comprise a first portion on which the electrical interface is disposed and a second portion composing the probe head assembly. The second portion of the wiring substrate can be moveable with respect to the first portion of the wiring substrate.