It is herein described a contact probe of a testing head of an apparatus for testing electronic devices comprising a probe body being essentially extended in a longitudinal direction between respective end portions adapted to realize a contact with respective contact pads, at least one end portion having transverse dimensions greater than the probe body and comprising an enlarged portion, projecting only in correspondence of a first side wall of the contact probe. Suitably, the at least one end portion further comprises at least one protrusion projecting from a second side wall, opposite to the first side wall and substantially extending toward the second and opposite wall along a longitudinal axis of the contact probe starting from the enlarged portion.

A testing substrate includes a first build-up structure and a ceramic substrate. The ceramic substrate is arranged on the first build-up structure. The first bonding interface between the first build-up structure and the ceramic substrate includes a dielectric-to-dielectric bonding interface and a metal-to-metal bonding interface. A manufacturing method of a testing substrate and a probe card are also provided.

A testing substrate includes a substrate and a first build-up structure. The substrate has a first surface and a second surface opposite to each other. The substrate includes a first conductive pattern. The first conductive pattern includes a plurality of conductive connectors, and each conductive connector penetrates the substrate from the first surface to the second surface of the substrate. The first build-up structure is arranged on the first surface. The first build-up structure has a second conductive pattern. The first conductive pattern is electrically connected to the second conductive pattern, and the size of the first conductive pattern is larger than or equal to the size of the second conductive pattern. A manufacturing method of the testing substrate and a probe card are also provided.

Proposed are an anodic aluminum oxide structure made of anodic aluminum oxide, a probe head having the same, and a probe card having the same. More particularly, proposed are an anodic aluminum oxide structure that has a fine size and pitch guide hole and facilitates insertion of a probe, a probe head having the same, and a probe card having the same.

A test kit for testing a device under test (DUT) includes a socket structure for containing the DUT, and a plunger assembly detachably coupled with the socket structure. The plunger assembly includes a multi-layered structure having at least an interposer substrate sandwiched by a top socket and a nest.

A testing probe structure for wafer level testing semiconductor IC packaged devices under test (DUT). The structure includes a substrate, through substrate vias, a bump array formed on a first surface of the substrate for engaging a probe card, and at least one probing unit on a second surface of the substrate. The probing unit includes a conductive probe pad formed on one surface of the substrate and at least one microbump interconnected to the pad. The pads are electrically coupled to the bump array through the vias. Some embodiments include a plurality of microbumps associated with the pad which are configured to engage a mating array of microbumps on the DUT. In some embodiments, the DUT may be probed by applying test signals from a probe card through the bump and microbump arrays without direct probing of the DUT microbumps.

The present invention provides a device for testing a chip, wherein the device includes a testing board and an interposer. The testing board has a plurality of pads for providing a plurality of test signals. The interposer board includes a plurality of passive components, and at least one of the passive components is coupled between a supply voltage and a ground voltage, and the supply voltage and the ground voltage are received from a power pad and a ground pad of the plurality of pads of the testing board, respectively; wherein the chip is positioned in the device, the chip receives the test signals including the supply voltage and the ground voltage from the power pad and the ground pad of the testing board, respectively.

A wafer test device includes a test interconnect to interface with a microcircuit of the wafer at a first side and an interposer to interface with the test interconnect at a second side of the test interconnect, opposite the first side. The interposer connects the test interconnect, via a printed circuit board (PCB), to a test apparatus that determines and controls test patterns that are applied to the microcircuit via the test interconnect. A support structure supports the test interconnect and the interposer. The support structure includes an inner bearing to tilt the test interconnect to match a tilt of a surface of the microcircuit. An elastomer between the test interconnect and the interposer reduces deflection of the test interconnect during a process of connecting the test interconnect to the microcircuit.

A relay pogo contact first charged device model test head apparatus for relay-based contact first field induced charged device model testing has a ground plane of conductive material, a coaxial connector whose outer conductor electrically connects to the ground plane, a current-sensing element with one terminal electrically connects to the ground plane and the other terminal electrically connects to the center conductor of the coaxial connector, a switch where the first terminal electrically connects to a center conductor of the coaxial connector, and a probe with one end electrically connected to a second terminal of the switch and the other end exposed to contact external objects.

A probe card device including a probe structure is provided. Probes respectively pass through multiple through holes on at least two guide plates that are stacked and separated from each other, and each of the probes includes a main body, a contacting portion, a head portion, and a neck portion. The contacting portion is exposed under a lowermost guide plate. The head portion is exposed above an uppermost guide plate. The neck portion is connected between the main body and the head portion, and a part of the neck portion protrudes opposite thereof to form a protrusion portion. The protrusion portion and the main body form an included angle, the protrusion portion abuts against an upper surface of the uppermost guide plate, and a spacing between any two of the probes that are adjacent to each other is less than twice the thickness of the protrusion portion.