Abstract: A probe for testing an electrical device under test. The probe has at least two outer layers and a core layer that is highly conductive. The core layer is disposed between the outer layers.

Abstract: An electrical element can be attached and electrically connected to a substrate by a conductive adhesive material. The conductive adhesive material can electrically connect the electrical element to a terminal or other electrical conductor on the substrate. The conductive adhesive material can be cured by directing a flow of heated gas onto the material or by heating the material through a support structure on which the substrate is located. A non-conductive adhesive material can attach the electrical element to the substrate with a greater adhesive strength than the conductive adhesive. The non-conductive adhesive material can also be cured by directing a flow of heated gas onto the material or by heating the material through the support structure on which the substrate is located. The non-conductive adhesive material can cover the conductive adhesive material.

Abstract: An electrically conductive probe can comprise a post to which a beam structure is attached. The beam structure can comprise a cantilevered portion that extends away from the post to a free end to which a contact structure can be attached. The cantilevered portion of the beam can include both a solid section and a hollow section. Multiple such probes can be used in a test contactor to make electrical connections with an electronic device such as a semiconductor die or dies to be tested.

Abstract: A probe card assembly can include a wireless link to an external verifier (e.g., debugger). The wireless link can interface to a boundary scan interface of a controller on the probe card assembly. The wireless link can allow for verification of the probe card assembly while it is installed within a prober.

Abstract: An apparatus and method providing improved interconnection elements and tip structures for effecting pressure connections between terminals of electronic components is described. The tip structure of the present invention has a sharpened blade oriented on the upper surface of the tip structure such that the length of the blade is substantially parallel to the direction of horizontal movement of the tip structure as the tip structure deflects across the terminal of an electronic component. In this manner, the sharpened substantially parallel oriented blade slices cleanly through any non-conductive layer(s) on the surface of the terminal and provides a reliable electrical connection between the interconnection element and the terminal of the electrical component.

Abstract: Techniques for testing an electronic device with through-device vias can include using a probe card assembly with probes for contacting connection structures of the electronic device including ends of through-device vias of the electronic device. A pair of the probes can be electrically connected in the probe card assembly and can thus contact and form a direct return loop from one through-device via to another through-device via of a pair of the through-device vias with which the pair of probes is in contact. The electronic device can include test circuitry for driving a test signal onto the one of the through-device vias and a receiver for detecting the test signal on the other of the through-device vias.

Abstract: A probe card apparatus can comprise a tester interface to a test controller, probes for contacting terminals of electronic devices to be tested, and electrical connections there between. The probe card apparatus can comprise a primary sub-assembly, which can include the tester interface. The probe card apparatus can also comprise an interchangeable probe head, which can include the probes. The interchangeable probe head can be attached to and detached from the primary sub-assembly while the primary sub-assembly is secured to or in a housing of a test system. Different probe heads each having probes disposed in different patterns to test different types of electronic devices can thus be interchanged while the primary sub-assembly is secured to or in a housing of the test system.

Abstract: A probe card assembly can comprise a guide plate comprising probe guides for holding probes in predetermined positions. The probe card assembly can also comprise a wiring structure attached to the guide plate so that connection tips of the probes are positioned against and attached to contacts on the wiring structure. The attachment of the guide plate to the wiring structure can allow the wiring structure to expand or contract at a greater rate than the guide plate. The probes can include compliant elements that fail upon high electrical current and thermal stresses located away from the contact tips.

Abstract: Contacts of an electrical device can be made of carbon nanotube columns. Contact tips can be disposed at ends of the columns. The contact tips can be made of an electrically conductive paste applied to the ends of the columns and cured (e.g., hardened). The paste can be applied, cured, and/or otherwise treated to make the contact tips in desired shapes. The carbon nanotube columns can be encapsulated in an elastic material that can impart the dominant mechanical characteristics, such as spring characteristics, to the contacts. The contacts can be electrically conductive and can be utilized to make pressure-based electrical connections with electrical terminals or other contact structures of another device.

Abstract: Methods and apparatus for testing devices using serially controlled intelligent switches have been described. In some embodiments, a probe card assembly can be provided that includes a plurality of integrated circuits (ICs) serially coupled to form a chain, the chain coupled to at least one serial control line, the plurality of ICs including switches coupled to test probes, each of the switches being programmable responsive to a control signal on the at least one serial control line.

Abstract: Wafer cassette systems and methods of using wafer cassette systems. A wafer cassette system can include a base and a probe card assembly. The base and the probe card assembly can each include complementary interlocking alignment elements. The alignment elements can constrain relative movement of the base and probe card assembly in directions parallel to a wafer receiving surface of the base, while permitting relative movement in a direction perpendicular to the receiving surface.

Abstract: Probes suitable for use with densely packed fine-pitch 2-D contact arrays are provided by use of an electrically insulating guide plate in connection with vertical probes, where the vertical probes have probe flexures that are either vertically folded sections, or coils having a horizontal axis. Preferably, the probes are configured such that the probe flexures are inside the guide plate holes, and the parts of the probes extending past the guide plate are relatively rigid. This configuration alleviates problems associate with probe shorting, because the probe flexures are enclosed by the guide plate holes, and are therefore unable to come into contact with flexures from other probes during probing.

Abstract: An improved method and apparatus for automatically aligning probe pins to the test or bond pads of semiconductor devices under changing conditions. In at least one embodiment, a dynamic model is used to predict an impact of changing conditions to wafer probing process. This reduces the need for frequent measurements and calibrations during probing and testing, thereby increasing the number of dice that can be probed and tested in a given period of time and increasing the accuracy of probing at the same time. Embodiments of the present invention also make it possible to adjust positions of probe pins and pads in response to the changing conditions while they are in contact with each other.

Abstract: A method of making carbon nanotube contact structures on an electronic device includes growing a plurality of carbon nanotube columns on a mandrel. Electrically-conductive adhesive is applied to ends of the columns distal from the mandrel, and the columns are transferred to the electronic device. An electrically-conductive material is deposited onto some or all of the columns. The mandrel can be reused to grow a second plurality of carbon nanotube columns.

Abstract: A stiffener for a probe card assembly can include decoupling mechanisms disposed within radial arms of the stiffener. The decoupling mechanisms can be compliant in a direction along a radial direction of said radial arm and rigid in a direction perpendicular to said radial arm. The decoupling mechanisms can decouple the stiffener from thermally induced differential radial contraction and expansion of the stiffener relative to the cardholder to which the stiffener is mounted. This can reduce thermally-induced vertical translation of the probe card assembly.

Abstract: Electrically conductive columns of intertwined carbon nanotubes embedded in a mass of material flexible, resilient electrically insulating material can be used as electrically conductive contact probes. The columns can extend between opposing sides of the mass of material. Terminals of a wiring substrate can extend into the columns and be electrically connected to an electrical interface to a tester that controls testing of a device under test. A pair of physically interlocked structures can coupling the mass of material to the wiring substrate. The pair can include a receptacle and a protrusion.

Abstract: Elongated flexible probes can be disposed in holes of upper and lower guide plates of a probe card assembly. Each probe can include one or more spring mechanisms that exert normal forces against sidewalls of holes in one of the guide plates. The normal forces can result in frictional forces against the sidewalls that are substantially parallel to the sidewalls. The frictional forces can reduce or impede movement parallel to the sidewalls of the probes in the holes.

Abstract: Methods and systems, in one embodiment, for receiving a warped flexible wafer to be transferred between a first mechanism and a second mechanism are described. The method and system senses a first vacuum suction between the warped flexible wafer and the first mechanism. The warped flexible wafer is positioned to define a gap between the warped flexible wafer and the second mechanism. Methods and systems for closing the gap incrementally between the warped flexible wafer and the second mechanism are described. At each increment, the methods and systems detect whether a second vacuum suction is created between the warped flexible wafer and the second mechanism. When a second vacuum suction is detected between the warped flexible wafer and the second mechanism, the first vacuum suction between the warped flexible wafer and the first mechanism is released.

Abstract: A fuel cell comprises an anode, a cathode, and a proton exchange membrane. The anode and cathode can include a catalyst layer which includes a plurality of generally aligned carbon nanotubes. Methods of making a fuel cell are also disclosed.

Abstract: A testing method (and the probes used) comprising providing one or more probes each comprising: a body portion which is substantially straight; an extended portion extending from the body portion and comprising at least two separate probe portions; and a tip portion at the opposite end of the extended portion; and contacting an object to be tested with the one or more probes.