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.

An apparatus for probing a device-under-test (DUT) includes a fixture disposed over the DUT, a circuitry film disposed along a contour of the fixture, a first signal connector, and a plurality of probing tips disposed on the circuitry film and extending toward the device-under-test. The circuitry film includes a first portion attached to a top sidewall of the fixture, and the first signal connector is disposed on and electrically connected to the first portion of the circuitry film. The first signal connector is electrically coupled to the probing tips through the circuitry film. A method for probing a DUT is also provided.

An inspection apparatus includes: a probe card having a probe to be in contact with an object to be inspected; an upper module having a mounting portion on which the object to be inspected is mounted; a movement mechanism that is configured to support the upper module to be liftable and lowerable and that is able to move the upper module in a horizontal direction; and a lifting and lowering mechanism that is provided under the movement mechanism and that is able to push up the upper module toward the probe card, wherein an axis passing through a point of action of a pushing force when the lifting and lowering mechanism pushes up the upper module and an axis passing through a point of action of a load received by the probe card are arranged at positions to be common.

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 probe card device includes a printed circuit board (PCB), a space transformer, and a high-speed flexible printed circuit (FPC). The PCB includes a plurality of first connecting bodies coupled to a tester, and a plurality of second connecting bodies. The space transformer includes a plurality of connecting bodies disposed on a first surface of the space transformer and coupled to the plurality of second connecting bodies of the printed circuit board, a plurality of general contact pads disposed on a second surface of the space transformer and contacted with a plurality of first probes, and a plurality of high-speed contact pads disposed on the second surface of the space transformer and contacted with a plurality of second probes. The high-speed FPC has a first connecting terminal coupled to the tester, and a second connecting terminal coupled to the plurality of high-speed contact pads.

A probe card includes a flexible inorganic material layer, a metal micro structure, and a circuit board. The flexible inorganic material layer has a first surface and a second surface opposite to each other. The metal micro structure is disposed on the first surface. The circuit board is disposed on the second surface, and the circuit board is electrically connected to the metal micro structure. The test signal is adapted to be conducted to the circuit board through the flexible inorganic material layer.

An electrical contact assembly that uses an elastomer strip for each row of individual contacts. Each contact comprises a rigid bottom pin and a flexible top pin with a pair of arms which extend over and slide along sloped concave surfaces of the bottom contact. The elastomer strip is located between rows of the bottom and top pins. A bottom socket housing is provided with grooves which receive each elastomer strip. A row of top pins is then placed over each elastomer strip, and through ducts in the bottom socket housing. Bottom pins are then snapped into place in between the pair of arms.

A wafer testing probe card includes a printed circuit board, a flexible circuit board, an elastic piece, and a probe unit. The flexible circuit board is electrically connected to the printed circuit board. The elastic piece is disposed between the printed circuit board and the flexible circuit board. The probe unit includes a probe head and a plurality of probes. The probe head is fixed on the printed circuit board and has a plurality of through holes. The probes respectively pass through the through holes and move up and down relative to the probe head.

The present invention relates to a method for realizing the measuring slip of membrane probe, wherein: an elastomer layer is placed between the rigid acting surface of the membrane probe head and the membrane on which the probe is arranged; on the axial plane of the probe, the elastomer layer takes any axial line passing through the probe as a boundary line, and there is a difference between the thickness of one side and thickness of the other side, so that the probe can deflect during the test, resulting in the measuring slip to penetrate or push away the surface oxide of the tested chip and achieve more stable contact.

A membrane probe card and its probe head, and the membrane probe card comprises a membrane probe head, and the membrane probe head consists of a support, membrane, a probe and an interconnecting wire; a concave supporting structure is arranged between the acting surface of the support and the membrane; the concave supporting structure comprises a concave structure and a supporting elastic layer, and the concave structure comprises one or more concaves, the concave corresponds to the position of the probe and the concaves are eccentric with the corresponding probes; the convex insert of the supporting elastic layer is embedded in the corresponding concave to generate a thickness difference between the two sides of each probe on the supporting elastic layer.