Abstract: Systems and methods for electrically testing electromigration in an electromigration test structure are disclosed herein. The systems include a voltage control portion, a current control portion, and a current regulating structure. The systems further include an electric current detector, a first system connection, and a second system connection. The systems also include a voltage detector, and a controller. In some embodiments of the methods, a voltage control portion regulates a high-side signal electric current to maintain a voltage difference below a voltage setpoint while a current control portion maintains the high-side signal electric current below a threshold current value. In some embodiments of the methods, one of the voltage difference and a magnitude of the high-side signal electric current is selected as a primary control parameter while the other is selected as a compliant control parameter.

Abstract: A multiple conduction path probe can provide an electrically conductive signal path from a first contact end to a second contact end. The probe can also include an electrically conductive secondary path and an electrically insulated gap between the signal path and the secondary path. A probe assembly can comprise multiple such probes disposed in passages in substantially parallel electrically conductive guide plates. In some configurations, the probe assembly can include one or more secondary probes disposed in passages of the conductive guide plates and electrically connected to one or both of the guide plates. Some of the probes can be electrically insulated from the guide plates and thus provide signal paths, and others of the probes can be electrically connected to the guide plates and thus provide secondary paths.

Abstract: Probe head assemblies and probe systems for testing integrated circuit devices are disclosed herein. In one embodiment, the probe head assemblies include a contacting structure and a space transformer assembly. In another embodiment, the probe head assemblies include a contacting structure, a suspension system, a flex cable interface, and a space transformer including a space transformer body and a flex cable assembly. In another embodiment, the probe head assemblies include a contacting structure, a space transformer, and a planarization layer. In another embodiment, the probe head assemblies include a contacting structure, a space transformer, a suspension system, a platen, a printed circuit board, a first plurality of signal conductors configured to convey a first plurality of signals external to the space transformer, and a second plurality of signal conductors configured to convey a second plurality of signals via the space transformer. The probe systems include the probe head assemblies.

Abstract: Shielded probe systems are disclosed herein. The probe systems are configured to test a device under test (DUT) and include a measurement chamber that at least partially bounds an enclosed volume, an aperture defined by the measurement chamber, a probing assembly, and a shielding structure. The probing assembly includes a probe, which is oriented within the enclosed volume, a probe arm, which is operatively attached to the probe, and a manipulator, which is operatively attached to the probe arm. At least a portion of the probing assembly extends through the aperture. The shielding structure extends between the measurement chamber and the probing assembly and is configured to restrict fluid flow through the aperture and shield the enclosed volume from an ambient environment that surrounds the measurement chamber while maintaining at least a threshold separation distance from the probe arm throughout a probe arm range-of-motion thereof.

Abstract: A chuck for testing an integrated circuit includes an upper conductive layer having a lower surface and an upper surface suitable to support a device under test. An upper insulating layer has an upper surface at least in partial face-to-face contact with the lower surface of the upper conductive layer, and a lower surface. A middle conductive layer has an upper surface at least in partial face-to-face contact with the lower surface of the upper insulating layer, and a lower surface.

Abstract: Probe systems, storage media, and methods for wafer-level testing over extended temperature ranges are disclosed herein. The methods are configured to test a plurality of devices under test (DUTs) present on a substrate. The probe systems are programmed to perform the methods. The storage media include computer-readable instructions that direct a probe system to perform the methods.

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: A test socket for facilitating testing of a device under test (DUT) includes a holder comprising a mounting structure for attaching the holder to other components of the socket and a floating nest structure in which the DUT can be disposed. The floating nest structure can have a seat cavity sized and shaped to receive and hold the DUT such that at least some of the DUT terminals are in contact with corresponding contacts of a test board while the test socket is attached to the test board. A flexure located laterally between the mounting structure and the floating nest structure and can allow the nest structure to move relative to the mounting structure and thus float.

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: 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 probe card apparatus can comprise a tester interface to a test controller, probes for contacting terminals of electronic devices to be tested, and electrical connections there between. The probe card apparatus can comprise a primary sub-assembly, which can include the tester interface. The probe card apparatus can also comprise an interchangeable probe head, which can include the probes. The interchangeable probe head can be attached to and detached from the primary sub-assembly while the primary sub-assembly is secured to or in a housing of a test system. Different probe heads each having probes disposed in different patterns to test different types of electronic devices can thus be interchanged while the primary sub-assembly is secured to or in a housing of the test system.

Abstract: A probe card assembly can comprise a guide plate comprising probe guides for holding probes in predetermined positions. The probe card assembly can also comprise a wiring structure attached to the guide plate so that connection tips of the probes are positioned against and attached to contacts on the wiring structure. The attachment of the guide plate to the wiring structure can allow the wiring structure to expand or contract at a greater rate than the guide plate. The probes can include compliant elements that fail upon high electrical current and thermal stresses located away from the contact tips.

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: The present invention is a probe array for testing an electrical device under test comprising one or more ground/power probes and one or more signal probes and optionally a gas flow apparatus.

Abstract: A retention arrangement that includes one or more templates for securing and aligning probes for testing a device under test.

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 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: A probe having a conductive body and a contacting tip that is terminated by one or more blunt skates for engaging a conductive pad of a device under test (DUT) for performing electrical testing. The contacting tip has a certain width and the blunt skate is narrower than the tip width. The skate is aligned along a scrub direction and also has a certain curvature along the scrub direction such that it may undergo both a scrub motion and a self-cleaning rotation upon application of a contact force between the skate and the conductive pad. While the scrub motion clears oxide from the pad to establish electrical contact, the rotation removes debris from the skate and thus preserves a low contact resistance between the skate and the pad. The use of probes with one or more blunt skates and methods of using such self-cleaning probes are especially advantageous when testing DUTs with low-K conductive pads or other mechanically fragile pads that tend to be damaged by large contact force concentration.

Abstract: A probe for testing an electrical device under test. The probe has at least two outer layers and a core layer that is highly conductive. The core layer is disposed between the outer layers.

Abstract: An electrical element can be attached and electrically connected to a substrate by a conductive adhesive material. The conductive adhesive material can electrically connect the electrical element to a terminal or other electrical conductor on the substrate. The conductive adhesive material can be cured by directing a flow of heated gas onto the material or by heating the material through a support structure on which the substrate is located. A non-conductive adhesive material can attach the electrical element to the substrate with a greater adhesive strength than the conductive adhesive. The non-conductive adhesive material can also be cured by directing a flow of heated gas onto the material or by heating the material through the support structure on which the substrate is located. The non-conductive adhesive material can cover the conductive adhesive material.