Abstract: A semiconductor device test system may include a body providing an internal space, in which a test device is loaded, and a cover coupled to the body to cover the internal space. The cover may include a first cover including first openings two-dimensionally arranged and a second cover including second openings two-dimensionally arranged. An arrangement of the first openings may be different from an arrangement of the second openings.

Abstract: An electrical test probe according to an embodiment includes a probe main body portion having a connection end to a circuit of a probe base plate and made of a first metal material with resiliency, and a probe tip portion having a probe tip, made of a second metal material with higher hardness than that of the first metal material for the probe main body portion, and communicating with the probe main body portion, wherein the probe main body portion and the probe tip portion are provided with a current path made of an equal metal material extending from the probe tip to the connection end.

Abstract: A semiconductor socket including a substrate with a plurality of through holes extending from a first surface to a second surface. A conductive structure is disposed within the through holes A plurality of discrete contact members are located in the plurality of the through holes, within the conductive structure. The plurality of contact members each include a proximal end accessible from the second surface, and a distal end extending above the first surface. The conductive structure can be electrically coupled to circuit geometry. At least one dielectric layer is bonded to the second surface of the substrate with recesses corresponding to desired circuit geometry. A conductive material deposited in at least a portion of the recesses to form conductive traces redistributing terminal pitch of the proximal ends of the contact members.

Abstract: An apparatus for testing electric characteristics of a test object including first connection terminals on a bottom surface and second connection terminals on a top surface, the apparatus comprises a test board comprising first pads on a predetermined surface; a socket configured to electrically connect the test object to the test board; and a handler configured to transport the test object to the socket. The socket comprises a first connection unit configured to be electrically connected to the first connection terminals of the test object and a second connection unit configured to be electrically connected to the second connection terminals of the test object.

Abstract: Probes are directly patterned on a test substrate, thereby eliminating a need for an interposer. Probe contact structures are formed as a two-level structure having a greater lateral dimension for a lower level portion than for an upper level portion. First cavities are formed in a masking layer applied to a test substrate, filling the cavities with a conductive material, and planarizing the top surfaces of the conductive material portions to form lower level portions. Another masking layer is applied over the lower level portions and patterned to define second cavities having a smaller lateral dimension that the lower level portions. The second cavities are filled with at least one conductive material to form upper level portions of the probe contact structures. The upper level portion of each probe contact structure can be employed to penetrate a surface oxide of solder balls.

Abstract: A contactor assembly for automated testing a device under test (DUT) that includes a plurality of separate electrodes including a first electrode includes a tester load board and a contactor body coupled to the tester load board. A plurality of contactor pins carried by the contactor body includes a first contactor pin and a second contactor pin that are electrically coupled to the tester load board. The tester load board is configured to couple the plurality of contactor pins to automatic test equipment (ATE) for testing the DUT. The first contactor pin and second contactor pin are positioned to both contact the first electrode. A first path to the first contactor pin and a second path to the second contactor pin are electrically shorted together by the contactor assembly to be electrically in parallel to provide redundant paths to the first electrode during automated testing of the DUT.

Abstract: In one embodiment, a method for testing a plurality of singulated semiconductor die involves 1) placing each of the singulated semiconductor die on a surface of a die carrier, 2) mating an array of electrical contactors with the plurality of singulated semiconductor die, and then 3) performing electrical tests on the plurality of singulated semiconductor die, via the array of electrical contactors.

Abstract: A testing apparatus includes a thermal control chamber including a test room, which temperature is controlled within a testing temperature range; a carrier frame including a direction guiding unit installed securely within the test room and formed with one guiding groove and a carrier rod extending through the guiding groove in the direction guiding unit; and a clamping unit mounted on the carrier rod for clamping a display-panel module securely, wherein, movement of the carrier rod transversely within the guiding groove relative to the direction guiding unit results in disposing the display-panel module to extend along one of several testing directions for undergoing a burn-in test.

Abstract: The inspection of semiconductors or like substrates by the present mechanism minimizes deflection in the checkplate and probe card. An inspection device including a housing, a toggle assembly within the housing, an objective lens assembly attached within the toggle assembly including an objective coupled within an objective focus, wherein the objective focus is deflectable along an optics axis, and a cam assembly including a rotary cam and a window carrier, wherein the window carrier is moveable along the optics axis with rotation of the rotary cam, wherein the cam assembly is coupled to the toggle assembly with the objective and window are aligned along the optics axis.

Abstract: Provided is a test structure for wafer acceptance test (WAT). The test structure includes a row of a plurality of first pads electrically connecting to each other, a second pad, a third pad, a first peripheral metal line, and a second peripheral metal line. The second pad is disposed in the vicinity of a first end of the row, wherein the second pad is electrically disconnected to the first pads. The third pad is disposed in the vicinity of a second end of the row, wherein the third pad is electrically disconnected to the first pads. The first peripheral metal line is disposed at a first side of the row and electrically connected to the second pad. The second peripheral metal line is disposed at a second side of the row and electrically connected to the third pad.

Abstract: A method of testing a multi-die integrated circuit (IC) can include testing an inter-die connection of the multi-die IC. The inter-die connection can include a micro-bump coupling a first die to a second die. The method can include detecting whether a fault occurs during testing of the inter-die connection. Responsive to detecting the fault, the multi-die integrated circuit can be designated as including a faulty inter-die connection. Also described is an integrated circuit that includes a first die, a second die on which the first die may be disposed, a plurality of inter-die connections coupling the first die to the second die, and a plurality of probe pads, where each probe pad is coupled to at least one of the inter-die connections.

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: Provided is an active non-contact probe card including a carrier, a support base, a piezoelectric material layer, an active sensor array chip and a control circuit. The support base is disposed on the carrier. The piezoelectric material layer is connected with the support base. The position of the active sensor array chip with respect to the carrier is determined according to the thicknesses of the support base and the thicknesses of the piezoelectric material layer. A control circuit provides a control voltage to the piezoelectric material layer to control the thickness of the piezoelectric material layer, so as to adjust the position of the active sensor array chip with respect to the carrier.

Abstract: A contactor assembly for automated testing a device under test (DUT) that includes a plurality of separate electrodes including a first electrode includes a tester load board and a contactor body coupled to the tester load board. A plurality of contactor pins carried by the contactor body includes a first contactor pin and a second contactor pin that are electrically coupled to the tester load board. The tester load board is configured to couple the plurality of contactor pins to automatic test equipment (ATE) for testing the DUT. The first contactor pin and second contactor pin are positioned to both contact the first electrode. A first path to the first contactor pin and a second path to the second contactor pin are electrically shorted together by the contactor assembly to be electrically in parallel to provide redundant paths to the first electrode during automated testing of the DUT.

Abstract: Circuit boards are provided that include a functional portion and at least one removable test point portion. The removable test point portion may include test points which are accessed to verify whether the functional portion is operating properly or whether installed electronic components are electrically coupled to the board. If multiple boards are manufactured together on a single panel (in which the individual boards are broken off), the test points can be placed on bridges (e.g., removable portions) that connect the individual boards together during manufacturing and testing. Configurable test boards are also provided that can be adjusted to accommodate circuit boards of different size and electrical testing requirements. Methods and systems for testing these circuit boards are also provided.

Abstract: Disclosed is a contactor interconnect in an integrated circuit device test fixture comprises a plurality of contactor pins enabled to provide electrical contact with the contact points of an integrated circuit device, the contactor pins being mounted in the test fixture; and an electrical circuit coupled to two or more of the contactor pins of the test fixture, wherein the electrical circuit is isolated from other contactor pins of the plurality of contactor pins and wherein the electrical circuit is coupled to the two or more contactor pins by an electronically direct pathway.

Abstract: An improved efficiency system for testing electronic components in a motherboard/daughterboard assembly in which the daughterboard is mounted in spaced parallel relationship the to motherboard includes one or more device-under-test socket sub-assemblies having a test socket thereon for receiving a device-under-test and a connector component for disengagable connection to a complementary connector component on the daughterboard with the socket sub-assembly effecting interengagement of the complementary connector component on the daughterboard via an opening in the motherboard to allow ready access to the test socket for temporary installation, testing, and removal of a device-under-test.

Abstract: A set of first substrate and second substrate are manufactured with a built-in N-fold rotational symmetry around the center axis of each substrate, wherein N is an integer greater than 1. A set of N different interposers is provided such that an i-th interposer provides electrical connection between the first substrate and the second substrate with a rotational angle of (i?1)/N×2?. The first and second substrates are tested with each of the N different interposers therebetween. Once the rotational angle that provides the highest stacked chip yield is determined, the first and the second substrates can be bonded with an azimuthal rotation that provides the highest stacked chip yield.

Abstract: A test apparatus for an electronic device package is provided, which includes a test socket having a first portion with a recess for receiving an electronic device package having external terminals arranged in a terminal configuration and a second portion. An interchangeable insert board is disposed between the first portion and the second portion and extended on the recess, which includes first contact pads arranged in a first pad configuration compatible with the terminal configuration and facing the recess and second contact pads arranged in a second pad configuration and disposed between the first and the second portions. Trace layers each electrically connects one of the first contact pads to one of the second contact pads. The contact pins each penetrates through the second portion and electrically connects to one of the second pads, wherein the contact pins are arranged in a pin configuration compatible with the second pad configuration.

Abstract: The invention relates to an apparatus for testing an integrated circuit of an electronic device.

Abstract: A test apparatus includes a printed circuit board, a chip carrier socket, and a display circuit. The chip carrier socket includes a space to receive a chip including a plurality of pins, a plurality of contact terminals, and a grounded ground portion. The display circuit includes a power supply and a plurality of light-emitting elements. When the chip is received in the space, the ground portion contacts a middle portion of each pin. When a pin of the chip is normal, a distal end of the normal pin contacts a corresponding contact terminal to connect a corresponding light-emitting element to the ground portion, causing the light-emitting element to light up. When a pin of the chip is askew, a distal end of the askew pin cannot contact a corresponding contact terminal, the corresponding light-emitting element will not light up.