Patent application number | Description | Published |
20120074975 | MICRO POSITIONING TEST SOCKET AND METHODS FOR ACTIVE PRECISION ALIGNMENT AND CO-PLANARITY FEEDBACK - Methods and structures for testing a microelectronic packaging structure/device are described. Those methods may include placing a device in a floating carrier, wherein the floating carrier is coupled to a socket housing by pin dowels disposed in four corners of the socket housing, and wherein at least two actuating motors are disposed within the socket housing, and micro adjusting the device by utilizing a capacitive coupled or a fiber optic alignment system wherein a maximum measured capacitance or maximum measured intensity between alignment structures disposed in the socket housing and alignment package balls disposed within the device indicate optimal alignment of the device. Methods further include methods for active co-planarity detection through the use of a capacitive-coupled techniques. | 03-29-2012 |
20120299609 | POSITIONING AND SOCKETING FOR SEMICONDUCTOR DICE - Devices and methods useful for testing bare and packaged semiconductor dice are provided. As integrated circuit chips become smaller and increasingly complex, the interface presented by a chip for connectivity with power supplies and other components of the system into which it is integrated similarly becomes smaller and more complex. Embodiments of the invention provide micron-scale accuracy alignment capabilities for fine pitch device first level interconnect areas. Embodiments of the invention employ air-bearings to effectuate the movement and alignment of a device under test with a testing interface. Additionally, testing interfaces comprising membranes supported by thermal fluids are provided. | 11-29-2012 |
20130269173 | APPARATUS AND METHOD FOR AUTOMATED SORT PROBE ASSEMBLY AND REPAIR - An apparatus comprising a robot; an end effector coupled to the robot and configured to grasp or transfer a probe of a size for use in a probe card; and instructions stored on a machine readable medium coupled to the robot, the instructions comprising to configure the robot to transfer a probe to a probe card substrate or, where the probe is attached to a probe card substrate, to move the probe. A method comprising automatically transferring a probe to a probe card substrate in an assembly process or, where the probe is attached to a probe card substrate, moving the probe in a repair process; and after transferring or moving the probe, heating the probe with a heat source. | 10-17-2013 |
20140090816 | ADJUSTABLE HEAT PIPE THERMAL UNIT - Assemblies and methods are described. One assembly includes a first plate and a second plate. The assembly also includes an adjustable heat pipe positioned between the first plate and the second plate, the adjustable heat pipe being in thermal contact with the first plate and the second plate. In another aspect, a plurality of springs may be positioned between the first plate and the second plate. Other embodiments are described and claimed. | 04-03-2014 |
20140176172 | COMPOSITE WIRE PROBE TEST ASSEMBLY - An examples includes a substrate, including a conductive trace and a layer disposed on top of the conductive trace, the layer defining at least one cavity extending to the conductive trace and an electrical probe disposed in the cavity, with solder coupling the electrical probe to the conductive trace. The electrical probe can include a high yield strength wire core including a refractory metal and a thin oxidation protection layer concentrically disposed around high yield strength wire core and providing an outside surface of the electrical probe, the thin oxidation protection layer including predominantly one or more materials selected from gold, platinum, ruthenium, rhodium, palladium, osmium, iridium, chromium, and combinations thereof, wherein the solder fills the cavity and is coupled to the electrical probe inside the cavity, disposed between the electrical probe and the layer. | 06-26-2014 |
20140218061 | MICRO POSITIONING TEST SOCKET AND METHODS FOR ACTIVE PRECISION ALIGNMENT AND CO-PLANARITY FEEDBACK - Methods and structures for testing a microelectronic packaging structure/device are described. Those methods may include placing a device in a floating carrier, wherein the floating carrier is coupled to a socket housing by pin dowels disposed in four corners of the socket housing, and wherein at least two actuating motors are disposed within the socket housing, and micro adjusting the device by utilizing a capacitive coupled or a fiber optic alignment system wherein a maximum measured capacitance or maximum measured intensity between alignment structures disposed in the socket housing and alignment package balls disposed within the device indicate optimal alignment of the device. Methods further include methods for active co-planarity detection through the use of a capacitive-coupled techniques. | 08-07-2014 |
20140239995 | TEST PROBES - The formation of test probe structures is described. One test probe structure includes a tip portion and a handle portion spaced a distance away from the tip portion. The test probe structure also includes a body bend portion positioned between the tip portion and the handle portion, and an intermediate portion positioned between the body bend portion and the handle portion. The body bend portion may include a curved shape extending from the intermediate portion to the tip portion. The tip portion may be formed to be offset from a longitudinal axis defined by the intermediate portion. The test probe structure defines a length and includes a cross-sectional area that is different at a plurality of positions along the length. Other embodiments are described and claimed. | 08-28-2014 |
20150061713 | ANTI-ROTATION FOR WIRE PROBES IN A PROBE HEAD OF A DIE TESTER - Wire probes are described that resist rotation during assembly into a probe head of a die tester. One example includes probe wires with a protrusion at a pre-determined position along the length of the wire. A probe substrate with pads on one side each to attach to and electrically connect with a probe wire and a pads on the opposite side to connect to test equipment and a probe holder above the substrate with holes. Each hole holds a respective one of the probe wires against the probe substrate. Each hole also has a key to mate with a protrusion of a respective probe wire so that the protrusions engage the keys to prevent rotation of the respective wire. | 03-05-2015 |