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: Embodiments of reinforced resilient elements and methods for fabricating same are provided herein. In one embodiment, a reinforced resilient element includes a resilient element configured to electrically probe an unpackaged semiconductor device to be tested, the resilient element having a first end and an opposing second end; and a reinforcement member having a first end affixed to the resilient element at the first end thereof or at a point disposed between the first and the second ends of the resilient element, an opposing second end disposed in a direction towards the second end of the resilient element, and a resilient portion disposed between the first and second ends, wherein the resilient portion is not affixed to the resilient element.

Abstract: 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.

Abstract: A test system includes a communications channel that terminals in a probe, which contacts an input terminal of an electronic device to be tested. A resistor is connected between the communications channel near the probe and ground. The resistor reduces the input resistance of the terminal and thereby reduces the rise and fall times of the input terminal. The channel may be terminated in a branch having multiple paths in which each path is terminated with a probe for contacting a terminal on electronic devices to be tested. Isolation resistors are included in the branches to prevent a fault at one input terminal from propagating to the other input terminals. A shunt resistor is provided in each branch, which reduces the input resistance of the terminal and thereby reduces the rise and fall times of the input terminal. The shunt resistor may also be sized to reduce, minimize, or eliminate signal reflections back up the channel.

Abstract: Methods and apparatus for testing semiconductor devices are provided herein. In some embodiments, an assembly for testing semiconductor devices can include a probe card assembly; and a thermal barrier disposed proximate an upper surface of the probe card assembly, the thermal barrier can restrict thermal transfer between tester side boundary conditions and portions of the probe card assembly disposed beneath the thermal barrier.

Abstract: A method of designing and manufacturing a probe card assembly includes prefabricating one or more elements of the probe card assembly to one or more predefined designs. Thereafter, design data regarding a newly designed semiconductor device is received along with data describing the tester and testing algorithms to be used to test the semiconductor device. Using the received data, one or more of the prefabricated elements is selected. Again using the received data, one or more of the selected prefabricated elements is customized. The probe card assembly is then built using the selected and customized elements.

Abstract: Double-sided interposer assemblies and methods for forming and using them. In one example of the invention, an interposer comprises a substrate having a first surface and a second surface opposite of said first surface, a first plurality of contact elements disposed on said first side of said substrate, and a second plurality of contact elements disposed on said second surface of said substrate, wherein said interposer connects electronic devices via said first and said second plurality of contact elements.

Abstract: Rotating contact elements and methods of fabrication are provided herein. In one embodiment, a rotating contact element includes a tip having a first side configured to contact a device to be tested and an opposing second side; and a plurality of deformed members extending from the second side of the tip and arranged about a central axis thereof, wherein the tip rotates substantially about the central axis upon compression of the plurality of deformed members.

Abstract: 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.

Abstract: 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.

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: Embodiments of reinforced resilient elements and methods for fabricating same are provided herein. In one embodiment, a reinforced resilient element includes a resilient element configured to electrically probe a device to be tested, the resilient element having a first end and an opposing second end; and a reinforcement member having a first end affixed to the resilient element at the first end thereof or at a point disposed between the first and the second ends of the resilient element, an opposing second end disposed in a direction towards the second end of the resilient member, and a resilient portion disposed between the first and second ends, wherein the resilient portion is not affixed to the resilient member.

Abstract: A high fidelity “loop-back” or interconnection of terminal pads of an IC on a wafer being tested in production is provided, while simultaneously a DC or low frequency path is provided back to a test system. Two or more IC pads are connected by probes forming the “loop-back,” each probe forming an inductor, the probes being connected together through a trace in a substrate. A capacitor is then provided on a layer of the substrate connected to the trace to form a three-pole filter. To provide isolation of high frequency self-test signals between the probes and lower frequency signals of the test system, an inductor is placed in the path between the tester and probes. The inductor provides an “AC” or high frequency block between the test system and probes, while still allowing the test system to use DC or low frequency signals to verify continuity, leakage, and perform other DC parametric tests.

Abstract: Embodiments of reinforced resilient elements and methods for fabricating same are provided herein. In one embodiment, a reinforced resilient element includes a resilient element configured to electrically probe a device to be tested, the resilient element having a first end and an opposing second end; and a reinforcement member having a first end affixed to the resilient element at the first end thereof or at a point disposed between the first and the second ends of the resilient element, an opposing second end disposed in a direction towards the second end of the resilient member, and a resilient portion disposed between the first and second ends, wherein the resilient portion is not affixed to the resilient member.

Abstract: A probe card apparatus is configured to have a desired overall amount of compliance. The compliance of the probes of the probe card apparatus is determined, and an additional, predetermined amount of compliance is designed into the probe card apparatus so that the sum of the additional compliance and the compliance of the probes total the overall desired compliance of the probe card apparatus.

Abstract: Contact tip structures are fabricated on sacrificial substrates for subsequent joining to interconnection elements including composite interconnection elements, monolithic interconnection elements, tungsten needles of probe cards, contact bumps of membrane probes, and the like. The spatial relationship between the tip structures can lithographically be defined to very close tolerances. The metallurgy of the tip structures is independent of that of the interconnection element to which they are attached, by brazing, plating or the like. The contact tip structures are readily provided with topological (small, precise, projecting, non-planar) contact features, such as in the form of truncated pyramids, to optimize electrical pressure connections subsequently being made to terminals of electronic components. Elongate contact tip structures, adapted in use to function as spring contact elements without the necessity of being joined to resilient contact elements are described.

Abstract: An interconnection element of a spring (body) including a first resilient element with a first contact region and a second contact region and a first securing region and a second resilient element, with a third contact region and a second securing region. The second resilient element is coupled to the first resilient element through respective securing regions and positioned such that upon sufficient displacement of the first contact region toward the second resilient element, the second contact region will contact the third contact region. The interconnection, in one aspect, is of a size suitable for directly contacting a semiconductor device. A large substrate with a plurality of such interconnection elements can be used as a wafer-level contactor. The interconnection element, in another aspect, is of a size suitable for contacting a packaged semiconductor device, such as in an LGA package.

Abstract: 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.

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.