Abstract: A probe card assembly can include a plurality of probes disposed on a substrate and arranged to contact terminals of a semiconductor wafer. Switches can be disposed on the probe card assembly and provide for selective connection and disconnection of the probes from electrical interconnections on the probe card assembly.

Abstract: Embodiments of probe cards and methods for fabricating and using same are provided herein. In some embodiments, an apparatus for testing a device (DUT) may include a probe card configured for testing a DUT; a thermal management apparatus disposed on the probe card to heat and/or cool the probe card; a sensor disposed on the probe card and coupled to the thermal management apparatus to provide data to the thermal management apparatus corresponding to a temperature of a location of the probe card; a first connector disposed on the probe card and coupled to the thermal management apparatus for connecting to a first power source internal to a tester; and a second connector, different than the first connector, disposed on the probe card and coupled to the thermal management apparatus for connecting to a second power source external to the tester.

Abstract: A robust mechanical structure is provided to prevent small foundation structures formed on a substrate from detaching from the substrate surface. The strengthened structure is formed by plating a foundation metal layer on a seed layer and then embedding the plated foundation structure in an adhesive polymer material, such as epoxy. Components, such as spring probes, can then be constructed on the plated foundation. The adhesive polymer material better assures the adhesion of the metal foundation structure to the substrate surface by counteracting forces applied to an element, such as a spring probe, attached to the plated foundation.

Abstract: A probe card assembly includes a probe card, a space transformer having resilient contact structures (probe elements) mounted directly to (i.e., without the need for additional connecting wires or the like) and extending from terminals on a surface thereof, and an interposer disposed between the space transformer and the probe card. The space transformer and interposer are “stacked up” so that the orientation of the space transformer, hence the orientation of the tips of the probe elements, can be adjusted without changing the orientation of the probe card. Suitable mechanisms for adjusting the orientation of the space transformer, and for determining what adjustments to make, are disclosed. The interposer has resilient contact structures extending from both the top and bottom surfaces thereof, and ensures that electrical connections are maintained between the space transformer and the probe card throughout the space transformer's range of adjustment, by virtue of the interposer's inherent compliance.

Abstract: Carbon nanotube columns each comprising carbon nanotubes can be utilized as electrically conductive contact probes. The columns can be grown, and parameters of a process for growing the columns can be varied while the columns grow to vary mechanical characteristics of the columns along the growth length of the columns. Metal can then be deposited inside and/or on the outside of the columns, which can enhance the electrical conductivity of the columns. The metalized columns can be coupled to terminals of a wiring substrate. Contact tips can be formed at or attached to ends of the columns. The wiring substrate can be combined with other electronic components to form an electrical apparatus in which the carbon nanotube columns can function as contact probes.

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: Methods and systems, in one embodiment, are described related to a chuck with a plurality of vacuum grooves on a surface. Each single vacuum groove of the plurality of vacuum grooves has a single port connected with a single vacuum line coupled to a vacuum source. The single vacuum line is not shared with another groove and a restriction is applied to the single vacuum line in order to isolate each single vacuum groove.

Abstract: Semiconductor dies are stacked offset from one another so that terminals located along two edges of each die are exposed. The two edges of the dies having terminals may be oriented in the same direction. Electrical connections may connect terminals on one die with terminals on another die, and the stack may be disposed on a wiring substrate to which the terminals of the dies may be electrically connected.

Abstract: A probe card assembly can include an electrical interface to a test system for testing electronic devices such as semiconductor dies. The probe card assembly can also include probes located at a first side of the probe card assembly. The probes, which can be electrically connected to the electrical interface, can be configured to contact terminals of the electronic devices in the test system while the probe card assembly is attached to the test system. The probe card assembly can be configured to impede thermal flow from the probe card assembly to the test system at places of physical contact between the probe card assembly and the test system while the probe card assembly is attached to the test system.

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: Methods and systems for, in one embodiment, accelerating a stage through a clearance height in a first direction and decelerating the stage in the first direction while accelerating in a second direction are shown. The stage is moved in a third direction and a determination is made whether the stage movement in the second direction is below a threshold value before continuing to move the stage further in the third direction. The first direction is perpendicular to the second direction and is parallel and opposite to the third direction.

Abstract: An electrically conductive contact element can include a first base and a second base with elongate, spaced apart leaves between the bases. A first end of each leaf can be coupled to the first base and an opposite second end of the leaf can be coupled to the second base. A body of the leaf between the first end and the second end can be sufficiently elongate to respond to a force through said contact element substantially parallel with the first axis and the second axis by first compressing axially while said force is less than a buckling force and then bending while said force is greater than the buckling force.

Abstract: A technique for anchoring carbon nanotube columns to a substrate can include use of a filler material placed onto the surface of the substrate into area between the columns and surrounding a base portion of each of the columns.

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: Embodiments of the present invention can relate to probe card assemblies, multilayer support substrates for use therein, and methods of designing multilayer support substrates for use in probe card assemblies. In some embodiments, a probe card assembly may include a multilayer support substrate engineered to substantially match thermal expansion of a reference material over a desired temperature range; and a probe substrate coupled to the multilayer support substrate. In some embodiments, the reference material may be silicon.

Abstract: A probing apparatus can comprise a substrate, conductive signal traces, probes, and electromagnetic shielding. The substrate can have a first surface and a second surface opposite the first surface, and the electrically conductive first signal traces can be disposed on the first surface of the first substrate. The probes can be attached to the first signal traces, and the electromagnetic shielding structures can be disposed about the signal traces.

Abstract: A probe group can include multiple probes for testing devices having contact pads. The probes can comprise beams, contact tip structures, and mounting portions. The beams can provide for controlled deflection of the probes. The contact tip structures can be connected to the beams and can include contact portions for contacting with the devices. The mounting portions of the beams can be attached to support structures, which can be arranged in a staggered pattern. The beams located in a first row of the staggered pattern can include narrowing regions that lie substantially in line with the mounting portions of a second row of the beams.

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: A voltage regulator includes an input terminal for receiving a power input having a first voltage level, and an output terminal for generating a power output. A reference signal having a second voltage level is derived from the first voltage level adjusted with a predetermined offset value for controlling the power output to be at a third voltage level proportional to the second voltage level.

Abstract: A composite spring contact structure includes a structural component and a conduction component distinct from each other and having differing mechanical and electrical characteristics. The structural component can include a group of carbon nanotubes. A mechanical characteristic of the composite spring contact structure can be dominated by a mechanical characteristic of the structural component, and an electrical characteristic of the composite spring contact structure can be dominated by an electrical characteristic of the conduction component. Composite spring contact structures can be used in probe cards and other electronic devices. Various ways of making contact structures are also disclosed.