Abstract: An electronic device tester channel transmits a single test signal to multiple terminals of electronic devices under test (DUTs) through a set of isolation resistors. The tester channel employs feedback to automatically adjust the test signal voltage to compensate for affects of faults at any of the DUT terminals to prevent the faults from substantially affecting the test signal voltage.

Abstract: An apparatus and method providing improved interconnection elements and tip structures for effecting pressure connections between terminals of electronic components is described. The tip structure of the present invention has a sharpened blade oriented on the upper surface of the tip structure such that the length of the blade is substantially parallel to the direction of horizontal movement of the tip structure as the tip structure deflects across the terminal of an electronic component. In this manner, the sharpened substantially parallel oriented blade slices cleanly through any non-conductive layer(s) on the surface of the terminal and provides a reliable electrical connection between the interconnection element and the terminal of the electrical component.

Abstract: An electronic device tester channel transmits a single test signal to multiple terminals of electronic devices under test (DUTs) through a set of isolation resistors. The tester channel employs feedback to automatically adjust the test signal voltage to compensate for affects of faults at any of the DUT terminals to prevent the faults from substantially affecting the test signal voltage.

Abstract: An electronics module is assembled by demountably attaching integrated circuits to a module substrate. The module is then tested at a particular operating speed. If the module fails to operate correctly at the tested speed, the integrated circuit or circuits that caused the failure are removed and replaced with new integrated circuits, and the module is retested. Once it is determined that the module operates correctly at the tested speed, the module may be rated to operate at the tested speed and sold, or the module may be tested at a higher speed.

Abstract: An unsingulated semiconductor wafer is provided. Electrical interconnect elements are formed on the unsingulated wafer such that the interconnect elements are electrically connected to terminals of the semiconductor dice composing the wafer. At least a portion of the interconnect elements extend beyond the boundaries of the dice into the scribe streets separating the individual dice. Thereafter, the wafer is singulated into individual dice.

Abstract: A method and apparatus for detecting an arc condition in a semiconductor test system is disclosed. While probes in a semiconductor test system are being moved into or out of contact with a semiconductor wafer, the voltage level of power supplied to selected ones of the probes is monitored. If the voltage level of the power exceeds a level that could cause an arc between the probes and the semiconductor wafer while the wafer is being moved, an indication is generated that an arc condition has been detected.

Abstract: A plurality of contact elements, such as contact bumps or free-standing spring contacts including both monolithic and composite interconnection elements, are mounted to relatively small tile substrates which, in turn, are mounted and connected to a relatively large electronic component substrate, thereby populating the electronic component with a plurality of contact elements while avoiding the necessity of yielding the contact elements directly upon the electronic component. The relatively large electronic component is suitably a space transformer component of a probe card assembly. In this manner, pressure connections can be made to an entire semiconductor wafer, at once, to provide for wafer-level burn-in, and the like. Solder balls, z-axis conductive adhesive, or compliant connections are suitably employed for making electrical connections between the tile substrates and the electronic component.

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: Contact structures exhibiting resilience or compliance for a variety of electronic components are formed by bonding a free end of a wire to a substrate, configuring the wire into a wire stem having a springable shape, severing the wire stem, and overcoating the wire stem with at least one layer of a material chosen primarily for its structural (resiliency, compliance) characteristics. A variety of techniques for configuring, severing, and overcoating the wire stem are disclosed. In an exemplary embodiment, a free end of a wire stem is bonded to a contact area on a substrate, the wire stem is configured to have a springable shape, the wire stem is severed to be free-standing by an electrical discharge, and the free-standing wire stem is overcoated by plating. 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.

Abstract: Spring contact elements are fabricated by depositing at least one layer of metallic material into openings defined in masking layers deposited on a surface of a substrate which may be an electronic component such as an active semiconductor device. Each spring contact element has a base end, a contact end, and a central body portion. The contact end is offset in the z-axis (at a different height) and in at least one of the x and y directions from the base end. In this manner, a plurality of spring contact elements are fabricated in a prescribed spatial relationship with one another on the substrate. The spring contact elements make temporary (i.e., pressure) or permanent (e.g., joined by soldering or brazing or with a conductive adhesive) connections with terminals of another electronic component to effect electrical connections therebetween.

Abstract: An interconnect assembly and methods for making and using the assembly. An exemplary embodiment of an aspect of the invention includes a contact element which includes a base portion adapted to be adhered to a substrate and a beam portion connected to and extending from the base portion. The beam portion is designed to have a geometry which substantially optimizes stress across the beam portion when deflected (e.g. it is triangular in shape) and is adapted to be freestanding. An exemplary embodiment of another aspect of the invention involves a method for forming a contact element. This method includes forming a base portion to adhere to a substrate of an electrical assembly and forming a beam portion connected to the base portion. The beam portion extends from the base portion and is designed to have a geometry which substantially evenly distributes stress across the beam portion when deflected and is adapted to be freestanding.

Abstract: Interconnect assemblies and methods for forming and using them. In one example of the invention, an interconnect assembly comprises a substrate, a resilient contact element and a stop structure with an embedded circuit element. The resilient contact element is disposed on the substrate and has at least a portion thereof which is capable of moving to a first position, which is defined by the stop structure, in which the resilient contact element is in mechanical and electrical contact with another contact element. In another example of the invention, a stop structure is disposed on a first substrate with a first contact element, and this stop structure defines a first position of a resilient contact element, disposed on a second substrate, in which the resilient contact element is in mechanical and electrical contact with the first contact element.

Abstract: Interconnection elements for electronic components, exhibiting desirable mechanical characteristic (such as resiliency, for making pressure contacts) are formed by using a shaping tool (512) to shape an elongate core element (502) of a soft material (such as gold or soft copper wire) to have a springable shape (including cantilever beam, S-shape, U-shape), and overcoating the shaped core element with a hard material (such as nickel and its alloys), to impart to desired spring (resilient) characteristic to the resulting composite interconnection element. A final overcoat of a material having superior electrical qualities (e.g., electrical conductivity and/or solderability) may be applied to the composite interconnection element.

Abstract: A method of fabricating a large contactor (62) is provided wherein one or more contactor units (78) are mounted on a support substrate (74) such that contact elements (80) attached to the contactor units are suitably aligned. In this manner, a large area contactor can be prepared using a plurality of smaller contactor units. Preferably the contact elements on the plurality of contactor units are coplanar across the contactor units. This is particularly advantageous for making a large contactor for probing semiconductor devices on a wafer. This also can be useful for making a contactor capable of contacting devices across an entire semiconductor wafer. In one embodiment, the contactor units self-align during reflow of a joining material such as solder balls (134) or other reflowable material interconnecting the contactor units and the support substrate.

Abstract: According to aspect of the invention, a plating system is provided which includes a tank for containing a plating solution, a shaft extending into the tank, and a substrate holder mounted to the shaft. The shaft and the tank are rotatable relative to one another. The substrate holder is configured to support a substrate in position so that at least a first face of the substrate is exposed to the plating solution in the tank.

Abstract: An initial graph of nodes is created within a routing space, and the number and locations of the nodes in the graph are adjusted. Links are created between nodes of the graph, and traces between specified nodes are created through the linked graph.

Abstract: A system for testing a number of integrated circuit (IC) devices under test (DUTs) having interface circuitry coupled to a single or multi-channel tester for receiving data values from the tester and providing error information concerning the DUTs. The interface circuitry forwards data values (received from the tester over a single channel) to a number of DUTs in parallel. The circuitry performs comparisons using data values read from the DUTs, and in response generates error values indicative of the comparison. The error values may then be returned to the tester over the same or a different channel.

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: Surface-mount, solder-down sockets permit electronic components such as semiconductor packages to be releasably mounted to a circuit board or other electronic component. In an embodiment, resilient contact structures extend through a support substrate, and solder-ball (or other suitable) contact structures are disposed along the bottom of the support substrate in electrical contact with the ends of the resilient contact structures. Composite interconnection elements are used as the resilient contact structures disposed atop the support substrate. In an embodiment intended to receive an LGA-type semiconductor package, pressure contact is made between the resilient contact structures and external connection points of the semiconductor package with a contact force which is generally normal to the top surface of the support substrate.

Abstract: The present invention provides an ancillary electrical component in very close proximity to a semiconductor device, preferably mounted directly to the semiconductor device. In one preferred embodiment, the ancillary electrical component is a capacitor. In a preferred embodiment, a terminal is provided on the semiconductor device such that the capacitor can be electrically connected directly to the terminals, as by soldering or with conductive epoxy. Connecting the capacitor between terminals of a power loop provides superior noise and transient suppression. The very short path between the capacitor and the active circuit provides for extremely low inductance, allowing for the use of relatively small capacitors. The semiconductor device then is connected to an electronic device such as a PC board for further connection to other circuitry.