Abstract: 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.

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 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 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 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.

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: 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.

Abstract: Devices and methods for providing, making, and/or using an electronic apparatus having a wall structure adjacent a resilient contact structure on a substrate. The electronic apparatus can include a substrate and a plurality of electrically conductive resilient contact structures, which can extend from the substrate. A first of the contact structures can be part of an electrical path through the electronic apparatus. A first electrically conductive wall structure can also extend from the substrate, and the first wall structure can be disposed adjacent one of the contact structures. The first wall structure can be electrically connected to a return current path within the electronic apparatus for an alternating current signal or power on the first contact structure.

Abstract: 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.

Abstract: In at least one embodiment, an interface assembly is provided which is capable of connecting with a receptor. The interface assembly includes a connector, a base, and a linkage set between the connector and base. The linkage can include a spring assembly and a cable assembly. The connector is capable of connecting with the receptor to form electrical connections, fluid connections or other such connections. The spring assembly is a deformable member that is attached to the base and to the connector, such that the connector is capable of moving in six degrees of freedom. The cable assembly is attached to the base and the connector. The cable assembly is capable of limiting motion and positioning of the connector in at least one degree of freedom. As such, the cable assembly can set the connector at an initial position or within an initial region.

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: A method of fabricating a guard structure can include depositing an insulating material over at least a portion of electrical signal conductors disposed on a component of a probe card assembly, and depositing an electrically conductive material onto the insulating material and at least a portion of electrical guard conductors disposed on the component of the probe card assembly. Each signal conductor can be disposed between a pair of the guard conductors. The probe card assembly can include a plurality of probes disposed to contact an electronic device to be tested. The signal conductors can be part of electrical paths within the probe card assembly to the probes.

Abstract: A self propelled moving-filter beverage maker includes an invertible housing having an elongate chamber, a cover at one end removably sealingly engaged with the housing for enabling the introduction and removal of liquid, and a separate non-neutral density filter free to move longitudinally in the chamber; the filter has a cross-section conforming to that of the chamber to minimize liquid bypass and has perforations at its longitudinal ends to accommodate liquid flow through the filter as the filter moves through the liquid each time the housing is inverted.