Abstract: A method of making a probe (and the resulting probe) comprising providing a metal foil, creating a tip on an edge of the foil, and laser cutting a body of the probe from the foil with one or more tips at an end of the body.

Abstract: A wafer-scale probe card for temporary electrical contact to a sample wafer or other device, for burn-in and test. The card includes a plurality of directly metallized single-walled or multi-walled nanotubes contacting a pre-arranged electrical contact pattern on the probe card substrate. The nanotubes are arranged into bundles for forming electrical contacts between areas of the device under test and the probe card. The bundles are compressible along their length to allow a compressive force to be used for contacting the probe card substrate to the device under test. A strengthening material may be disposed around and/or infiltrate the bundles. The nanotubes forming the bundles may be patterned to provide a pre-determined bundle profile. Tips of the bundles may be metallized with a conductive material to form a conformal coating on the bundles; or metallized with a conductive material to form a continuous, single contact surface.

Abstract: A probe card assembly and associated processes of forming them may include a wiring substrate with a first surface and an opposite surface, an electrically conductive first via comprising electrically conductive material extending into the wiring substrate from the opposite surface and ending before reaching the first surface, and a plurality of electrically conductive second vias, and a custom electrically conductive terminal disposed on the first surface such that said custom terminal covers the first via and contacts one of the second vias adjacent to said first via without electrically contacting the first via. Each of the second vias may be electrically conductive from the first surface to the opposite surface. The first via may include electrically insulating material disposed within a hole in the first via.

Abstract: Embodiments of a multi-stage spring system are provided herein. In some embodiments, a multi-stage spring system includes a spring assembly having at least one resilient element, wherein the spring assembly has a first spring constant when deflected up to a first distance, a greater, second spring constant when deflected beyond the first distance and up to a second distance, and a greater, third spring constant when deflected beyond the second distance and up to a third distance, and wherein the spring assembly stores mechanical energy when deflected towards a contact surface that biases the spring assembly away from the contact surface when released.

Abstract: Methods and apparatuses for modifying a stage position and measuring at least one parameter of a motor connected with a stage during a commanded stage position are described. In one embodiment of one aspect of the invention, the motor is configured to move the stage in a first direction in response to the at least one parameter and determine whether the at least one parameter is within a threshold range.

Abstract: A probe head can comprise a substrate and electrically conductive structures extending from opposite surfaces of the substrate. The probe head can be made by forming frame structures each comprising a frame to which a row of the conductive structures is coupled. The frame structures can be placed in a stack. A compressible shim or a curable adhesive can be provided between adjacent frames in the stack to control a distance between the contact ends of the conductive structures in adjacent rows of the conductive structures. The frames can include cavities that form a mold while the frames are in the stack, and the substrate can be formed by introducing a moldable material into the mold. After the moldable material hardens, the frame can be removed, leaving the conductive structures embedded in the substrate.

Abstract: A probe card assembly can comprise a first source of compliance and a second source of compliance. The probe card assembly can further comprise a controller, which can be configured to apportion a total compliance demand placed on the probe card assembly between the first source of compliance and the second source of compliance.

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: Contact structures exhibiting resilience or compliance for a variety of electronic components are formed. A variety of materials for the wire stem (which serves as a falsework) and for the overcoat (which serves as a superstructure over the falsework) are disclosed. Various techniques are described for mounting the contact structures to a variety of electronic components (e.g., semiconductor wafers and dies, semiconductor packages, interposers, interconnect substrates, etc.), and various process sequences are described. The resilient contact structures described herein are ideal for making a “temporary” (probe) connections to an electronic component such as a semiconductor die, for burn-in and functional testing.

Abstract: The elongated body of an electrically conductive contact probe can be disposed in a guide hole and can include a patterned region for engaging and riding on a contact region of an inner sidewall of the guide hole as the elongated body moves in the guide hole in response to a force on a tip of the probe. As the patterned region rides the contact region, the tip moves in a lateral pattern that is a function of the surface(s) of the patterned region.

Abstract: One or more customization layers can be added to a wiring substrate. The customization layers can provide customized electrical connections from electrical contacts of the base wiring substrate to electrical contacts at an outer surface of the customization layers, which can allow the contacts at the outer surface of the customization layers can be in a different pattern than the contacts at the surface of the base wiring substrate. The customization layers can comprise electrically insulating material, electrically conductive via structures through the insulating material, electrically conductive traces, electrically conductive jumpers electrically connecting two traces without contacting a trace disposed between the two traces, and/or other such elements.

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: An electrical connection between an electrically conductive probe on one device and a compliant pad on another device can be formed by piercing the compliant pad with the probe. The probe can contact multiple electrically conductive elements inside the pad and thereby electrically connect to the pad at multiple locations inside the pad.

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 microelectronic probe element can include a base, a tip, and a spring assembly coupled between the tip and the base. The spring assembly can include a first spring and a second spring, wherein the first spring has a negative stiffness over a predefined displacement range and the second spring has a positive stiffness over the predefined displacement range. The first spring and second spring can be coupled so that the negative stiffness and positive stiffness substantially cancel to produce a net stiffness of the tip relative to the base over the predefined displacement range.

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: Methods, apparatus, and computer readable media for designing a custom test system are described. Examples of the invention can relate to a method of generating test system software for a semiconductor test system. In some examples, a method can include obtaining a configuration of the semiconductor test system, the configuration including a description of a device under test (DUT) and a description of test hardware; and generating an application programming interface (API) specific to the configuration of the semiconductor test system, the API being generated based on the description of the DUT and the description of the test hardware, the API providing a programming interface between the test system software and the test hardware to facilitate testing of the DUT.

Abstract: Improved probing of closely spaced contact pads is provided by an array of vertical probes having all of the probe tips aligned along a single contact line, while the probe bases are arranged in an array having two or more rows parallel to the contact line. With this arrangement of probes, the probe base thickness can be made greater than the contact pad spacing along the contact line, thereby advantageously increasing the lateral stiffness of the probes. The probe tip thickness is less than the contact pad spacing, so probes suitable for practicing the invention have a wide base section and a narrow tip section.

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: Method and apparatus for electrical testing of a device under test (DUT) that employs a connection board with signal contacts for applying test signals and a space transformer that has low pitch contacts arranged on one or more circumferential shelves that define an enclosure in the space transformer. The apparatus has a substrate with fine pitch contacts positioned such that these are within the enclosure. A set of wire bonds is used for pitch reduction by interconnecting the fine pitch contacts with the low pitch contacts arranged on the shelves. The probes are connected to the fine pitch contacts and are used to apply the test signals to a DUT by contacting its pads. In some embodiments, the fine pitch contacts may be embodied by plugs or by blind metal vias.