Abstract: 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.

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: 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.

Abstract: A cooling assembly includes a package with one or more dies cooled by direct cooling. The cooled package includes one or more dies with active electronic components. A coolant port allows a coolant to enter the package and directly cool the active electronic components of the dies.

Abstract: A probe system for providing signal paths between an integrated circuit (IC) tester and input/output, power and ground pads on the surfaces of ICs to be tested includes a probe board assembly, a flex cable and a set of probes arranged to contact the IC's I/O pads. The probe board assembly includes one or more rigid substrate layers with traces and vias formed on or within the substrate layers providing relatively low bandwidth signal paths linking the tester to probes accessing some of the IC's pads. The flex cable provides relatively high bandwidth signal paths linking the tester to probes accessing others of the IC's pads.

Abstract: Methods and apparatus for indirect planarization of a substrate are provided herein. In one embodiment, an apparatus for indirectly planarizing a probe card assembly includes an adjustment portion for controlling a force applied to a probe substrate of the probe card assembly; a force application portion configured to apply the force to the probe substrate at a location that is laterally offset from the adjustment portion; and a mechanism coupling the adjustment portion to the force application portion.

Abstract: A plurality of differential signal transmitters can transmit data signals differentially through a plurality of conductive signal lines. Ones of the signal lines can be shared between transmitters, and others of the signal lines need not be shared between transmitters.

Abstract: A planarizer for a probe card assembly. A planarizer includes a first control member extending from a substrate in a probe card assembly. The first control member extends through at least one substrate in the probe card assembly and is accessible from an exposed side of an exterior substrate in the probe card assembly. Actuating the first control member causes a deflection of the substrate connected to the first control member.

Abstract: A carbon nanotube contact structure can be used for making pressure connections to a DUT. The contact structure can be formed using a carbon nanotube film or with carbon nanotubes in solution. The carbon nanotube film can be grown in a trench in a sacrificial substrate in which a contact structure such as a beam or contact element is then formed by metal plating. The film can also be formed on a contact element and have metal posts dispersed therein to provide rigidity and elasticity. Contact structures or portions thereof can also be plated with a solution containing carbon nanotubes. The resulting contact structure can be tough, and can provide good electrical conductivity.

Abstract: 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.

Abstract: An exemplary die carrier is disclosed. In some embodiments, the die carrier can hold a plurality of singulated dies while the dies are tested. The dies can be arranged on the carrier in a pattern that facilities testing the dies. The carrier can be configured to allow interchangeable interfaces to different testers to be attached to and detached from the carrier. The carrier can also be configured as a shipping container for the dies.

Abstract: A probing apparatus can include a plurality of contact probes, which can be of a type that is disposed along an axis. Each contact probe can include a contact portion, a base portion, and resilient portion. Multiple arms can form the resilient portion, which can be disposed between the contact portion and the base portion. The contact probes can be configured to twist when compressed. The probing apparatus can also include a substrate with through holes, and the contact probes can be inserted into the through holes. The resilient portion of each of the contact probes can bias the contact portion such that at least a portion of the contact portion extends out of a through hole.

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, according to some embodiments of the invention, can comprise a tester interface configured to make electrical connections with a test controller, a plurality of electrically conductive probes disposed to contact terminals of an electronic device to be tested, and a plurality of electrically conductive data paths connecting the tester interface and the probes. At least one of the data paths can comprise an air bridge structure trace comprising an electrically conductive trace spaced away from an electrically conductive plate by a plurality of pylons.

Abstract: An electrical interconnect assembly and methods for making an electrical interconnect assembly. In one embodiment, an interconnect assembly includes a flexible wiring layer having a plurality of first contact elements and a fluid containing structure which is coupled to the flexible wiring layer. The fluid, when contained in the fluid containing structure, presses the flexible wiring layer towards a device under test to form electrical interconnections between the first contact elements and corresponding second contact elements on the device under test. In a further embodiment, an interconnect assembly includes a flexible wiring layer having a plurality of first contact terminals and a semiconductor substrate which includes a plurality of second contact terminals.

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: Microelectronic contact structures (260, 360, 460) are lithographically defined and fabricated by applying a masking layer (220, 320, 420) on a surface of a substrate (202, 302, 402) such as an electronic component, creating an opening (222, 322, 422) in the masking layer, depositing a conductive trace of a seed layer (250, 350, 450) onto the masking layer and into the openings, and building up a mass of conductive material on the conductive trace. The sidewalls of the opening can be sloped (tapered). The conductive trace can be patterned by depositing material through a stencil or shadow mask (240, 340, 440). A protruding feature (230, 430) may be disposed on the masking layer so that a tip end (264, 364, 464) of the contact structure acquires a topography. All of these elements can be constructed as a group to form a plurality of precisely positioned resilient contact structures.

Abstract: A main power source supplies current through path impedance to a power terminal of an integrated circuit device under test (DUT). The DUT's demand for current at the power input terminal temporarily increases following edges of a clock signal applied to the DUT during a test as transistors within the IC switch in response to the clock signal edges. To limit variation (noise) in voltage at the power input terminal, an auxiliary power supply supplies an additional current pulse to the power input terminal to meet the increased demand during each cycle of the clock signal. The magnitude of the current pulse is a function of a predicted increase in current demand during that clock cycle, and of the magnitude of an adaption signal controlled by a feedback circuit provided to limit variation in voltage developed at the DUT's power input terminal.

Abstract: An interconnection apparatus and a method of forming an interconnection apparatus. Contact structures are attached to or formed on a first substrate. The first substrate is attached to a second substrate, which is larger than the first substrate. Multiple such first substrates may be attached to the second substrate in order to create an array of contact structures. Each contact structure may be elongate and resilient and may comprise a core that is over coated with a material that imparts desired structural properties to the contact structure.

Abstract: An electronic device is moved into a first position such that terminals of the electronic device are adjacent probes for making electrical contact with the terminals. The electronic device is then moved horizontally or diagonally such that the terminals contact the probes. Test data are then communicated to and from the electronic device through the probes.