Patent application number | Description | Published |
20080203268 | ADJUSTMENT MECHANISM - A probe card assembly can comprise a support structure to which a plurality of probes can be directly or indirectly attached. The probes can be disposed to contact an electronic device to be tested. The probe card assembly can further comprise actuators, which can be configured to change selectively an attitude of the support structure with respect to a reference structure. The probe card assembly can also comprise a plurality of lockable compliant structures. While unlocked, the lockable compliant structures can allow the support structure to move with respect to the reference structure. While locked, however, the compliant structures can provide mechanical resistance to movement of the support structure with respect to the reference structure. | 08-28-2008 |
20080231258 | STIFFENING CONNECTOR AND PROBE CARD ASSEMBLY INCORPORATING SAME - A stiffening connector assembly and methods of use are provided herein. In some embodiments a stiffening connector assembly includes a connector configured to be coupled to a substrate; and a mechanism coupled to the connector and configured to restrict rotational movement of the connector with respect to the substrate when coupled thereto. The mechanism may further provide a lateral degree of freedom of movement in a direction substantially parallel to the substrate. | 09-25-2008 |
20090079452 | COMPONENT ASSEMBLY AND ALIGNMENT - A method or an apparatus for aligning a plurality of structures can include applying a first force in a first plane to a first structure. The method can also include constraining in the first plane the first structure with respect to a second structure such that the first structure is in a position with respect to the second structure that aligns first features on the first structure with second features on the second structures. The second feature can be in a second plane that is generally parallel to the first plane. The first and second structures can be first and second electronic components, which can be components of a probe card assembly. | 03-26-2009 |
20090108861 | STIFFENER ASSEMBLY FOR USE WITH TESTING DEVICES - A stiffener assembly for use with testing devices is provided herein. In some embodiments, a stiffener for use with testing devices includes an inner member; an outer member disposed in a predominantly spaced apart relation to the inner member; and a plurality of alignment mechanisms for orienting the inner and outer members with respect to each other, wherein the alignment mechanisms transfer forces applied to a lower surface of the inner member to the outer member and provide the predominant conductive heat transfer passageway between the inner and outer members. | 04-30-2009 |
20090158586 | METHOD AND APPARATUS FOR ADJUSTING A MULTI-SUBSTRATE PROBE STRUCTURE - A probe card assembly comprises multiple probe substrates attached to a mounting assembly. Each probe substrate includes a set of probes, and together, the sets of probes on each probe substrate compose an array of probes for contacting a device to be tested. Adjustment mechanisms are configured to impart forces to each probe substrate to move individually each substrate with respect to the mounting assembly. The adjustment mechanisms may translate each probe substrate in an “x,” “y,” and/or “z” direction and may further rotate each probe substrate about any one or more of the forgoing directions. The adjustment mechanisms may further change a shape of one or more of the probe substrates. The probes can thus be aligned and/or planarized with respect to contacts on the device to be tested. | 06-25-2009 |
20090206860 | APPARATUS AND METHOD FOR ADJUSTING THERMALLY INDUCED MOVEMENT OF ELECTRO-MECHANICAL ASSEMBLIES - A thermal adjustment apparatus for adjusting one or more thermally induced movements of an electro-mechanical assembly includes: a compensating element expanding at a first rate different from a second rate at which the electro-mechanical assembly expands for generating a counteracting force in response to changes in temperature; and a coupling mechanism coupling the compensating element to the electro-mechanical assembly, and being adjustable to control an amount of the counteracting force applied to the electro-mechanical assembly as temperature changes. | 08-20-2009 |
20090260960 | SWITCH FOR USE IN MICROELECTROMECHANICAL SYSTEMS (MEMS) AND MEMS DEVICES INCORPORATING SAME - Embodiments of the present invention provide microelectromechanical systems (MEMS) switching methods and apparatus having improved performance and lifetime as compared to conventional MEMS switches. In some embodiments, a MEMS switch may include a resilient contact element comprising a beam and a tip configured to wipe a contact surface; and a MEMS actuator having an open position that maintains the tip and the contact surface in a spaced apart relation and a closed position that brings the tip into contact with the contact surface, wherein the resilient contact element and the MEMS actuator are disposed on a substrate and are movable in a plane substantially parallel to the substrate. In some embodiments, various contact elements are provided for the MEMS switch. In some embodiments, various actuators are provided for control of the operation of the MEMS switch. | 10-22-2009 |
20100000080 | APPARATUS AND METHOD FOR MANAGING THERMALLY INDUCED MOTION OF A PROBE CARD ASSEMBLY - A probe card assembly can include a probe head assembly having probes for contacting an electronic device to be tested. The probe head assembly can be electrically connected to a wiring substrate and mechanically attached to a stiffener plate. The wiring substrate can provide electrical connections to a testing apparatus, and the stiffener plate can provide structure for attaching the probe card assembly to the testing apparatus. The stiffener plate can have a greater mechanical strength than the wiring substrate and can be less susceptible to thermally induced movement than the wiring substrate. The wiring substrate may be attached to the stiffener plate at a central location of the wiring substrate. Space may be provided at other locations where the wiring substrate is attached to the stiffener plate so that the wiring substrate can expand and contract with respect to the stiffener plate. | 01-07-2010 |
20100134127 | MECHANICAL DECOUPLING OF A PROBE CARD ASSEMBLY TO IMPROVE THERMAL RESPONSE - A stiffener structure, a wiring substrate, and a frame having a major surface disposed in a stack can be part of a probe card assembly. The wiring substrate can be disposed between the frame and the stiffener structure, and probe substrates can be coupled to the frame by one or more non-adjustably fixed coupling mechanisms. Each of the probe substrates can have probes that are electrically connected through the probe card assembly to an electrical interface on the wiring substrate to a test controller. The non-adjustably fixed coupling mechanisms can be simultaneously stiff in a first direction perpendicular to the major surface and flexible in a second direction generally parallel to the major surface. | 06-03-2010 |
20100134128 | Thermocentric Alignment Of Elements On Parts Of An Apparatus - A first device and a second device can include at least one alignment feature and at least one corresponding constraint. The alignment feature and the constraint can be configured to align the first device and the second device when the alignment feature is inserted into the constraint. The alignment feature and the constraint can be further configured to direct relative movement between the first device and the second device due to relative thermal expansion or contraction between the first device and the second device. The directed relative movement can keep the first device and the second device aligned over a predetermined temperature range. | 06-03-2010 |
20100134129 | MECHANICAL DECOUPLING OF A PROBE CARD ASSEMBLY TO IMPROVE THERMAL RESPONSE - A stiffener structure, a wiring substrate, and a frame having a major surface disposed in a stack can be part of a probe card assembly. The wiring substrate can be disposed between the frame and the stiffener structure, and probe substrates can be coupled to the frame by one or more non-adjustably fixed coupling mechanisms. Each of the probe substrates can have probes that are electrically connected through the probe card assembly to an electrical interface on the wiring substrate to a test controller. The non-adjustably fixed coupling mechanisms can be simultaneously stiff in a first direction perpendicular to the major surface and flexible in a second direction generally parallel to the major surface. | 06-03-2010 |
20100164323 | BIASED GAP-CLOSING ACTUATOR - A gap-closing actuator includes a stator having one or more first electrodes, a mover having one or more second electrodes interposed among the first electrodes, and a biasing mechanism for applying a non-capacitive bias to the mover for urging the mover to move in a desired direction with respect to the stator. The non-capacitive bias is different from a capacitive force generated between the first and second electrodes when the gap-closing actuator is in operation. | 07-01-2010 |
20100264949 | FLEXURE BAND AND USE THEREOF IN A PROBE CARD ASSEMBLY - A flexure band can comprise structures configured to have elastic properties. Such a band can be stretched but will return generally to its original shape after forces that stretched the band are removed. The flexure band can hold one or more temperature control devices against a peripheral edge of a stiffening frame in a probe card assembly, or the flexure band can itself be a temperature control device. The band can be made of a metal that can be selected to impart one or more of the following properties: low thermal conductivity, high specific heat, generates little to no appreciable contamination, and/or usable over a wide range of temperatures. A material can be added to the band as a full or partial coating that enhances or adds one or more of the above-mentioned possible properties of the metal band. | 10-21-2010 |
20100271062 | METHOD AND APPARATUS FOR PROBE CARD ALIGNMENT IN A TEST SYSTEM - Embodiments of methods and apparatus for aligning a probe card assembly in a test system are provided herein. In some embodiments, an apparatus for testing devices may include a probe card assembly having a plurality of probes, each probe having a tip for contacting a device to be tested, and having an identified set of one or more features that are preselected in accordance with selected criteria for aligning the probe card assembly within a prober after installation therein. In some embodiments, the identity of the identified set of one or more features may be communicated to the prober to facilitate a global alignment of the probe card assembly that minimizes an aggregate misalignment of all of the tips in the probe card assembly | 10-28-2010 |
20100327891 | METHOD AND APPARATUS FOR THERMALLY CONDITIONING PROBE CARDS - 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. | 12-30-2010 |
20110050265 | METHOD AND APPARATUS FOR MULTILAYER SUPPORT SUBSTRATE - 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. | 03-03-2011 |
20110128029 | STIFFENER ASSEMBLY FOR USE WITH TESTING DEVICES - A stiffener assembly for use with testing devices is provided herein. In some embodiments, a stiffener assembly for use with testing devices can be part of a probe card assembly that can include a stiffener assembly comprising an upper stiffener coupled to a plurality of lower stiffeners; and a substrate constrained between the upper stiffener and the plurality of lower stiffeners, the stiffener assembly restricting non-planar flex of the substrate while facilitating radial movement of the substrate with respect to the stiffener assembly. | 06-02-2011 |
20110156734 | TEST SYSTEMS AND METHODS FOR TESTING ELECTRONIC DEVICES - Devices under test (DUTs) can be tested in a test system that includes an aligner and test cells. A DUT can be moved into and clamped in an aligned position on a carrier in the aligner. In the align position, electrically conductive terminals of the DUT can be in a predetermined position with respect to carrier alignment features of the carrier. The DUT/carrier combination can then be moved from the aligner into one of the test cells, where alignment features of the carrier are mechanically coupled with alignment features of a contactor in the test cell. The mechanical coupling automatically aligns terminals of the DUT with probes of the contactor. The probes thus contact and make electrical connections with the terminals of the DUT. The DUT is then tested. The aligner and each of the test cells can be separate and independent devices so that a DUT can be aligned in the aligner while other DUTs, having previously been aligned to a carrier in the aligner, are tested in a test cell. | 06-30-2011 |
20110156735 | WAFER TEST CASSETTE SYSTEM - 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. | 06-30-2011 |
20120146679 | PROBE CARD STIFFENER WITH DECOUPLING - 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. | 06-14-2012 |
20120242363 | Non-Linear Vertical Leaf Spring - 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. | 09-27-2012 |