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 probe card apparatus for wafer testing of a wafer under test, and a method of using the probe card for wafer testing. The probe card includes a printed circuit board having wafer testing circuitry. The probe card also includes a probe array including a slab having a plurality of probes, wherein each probe includes a volume of electrically-conductive fluid contained within a corresponding perforation of the slab that extends between a first surface and a second surface of the slab, wherein a first surface of each volume of electrically-conductive fluid substantially coincides with the first surface of the slab.

A detection device includes: a metal body having a plurality of main vias, a plurality of main through holes with insulators formed on the hole walls of the main vias, and a plurality of connecting elements disposed in the main through holes. Therefore, when testing a chip with I/O pins of high density with the detection device, the connecting elements contact the insulator only, without contacting the hole walls of the main vias, and the problem of short circuits can be avoided. A method of forming a detection device is also provided.

The present disclosure provides a probe card device and a conductive probe thereof. The conductive probe includes a metallic pin, an outer electrode, and a dielectric layer. The metallic pin includes a middle segment, a first connecting segment and a second connecting segment respectively extending from two opposite ends of the middle segment, and a first contacting segment and a second contacting segment respectively extending from the first connecting segment and second contacting segment along two opposite directions away from the middle segment. At least part of the outer electrode corresponds in position to the middle segment and is arranged adjacent to the first connecting segment. The dielectric layer is sandwiched between and entirely separates the metallic pin and the outer electrode, so that the outer electrode, the dielectric layer, and the metallic pin are jointly configured to generate a capacitance effect.

A probe card includes a probe having a spring property and a probe head that holds the probe. The probe head includes a guide portion that holds the probe such that the probe can move in an axis direction Z. The guide portion includes a heat radiation structure that absorbs heat of the probe generated by energization and emits the heat to the outside of the probe.

An electrical connection device includes: a probe head (20) including a guide hole (200), in which a shape perpendicular to an extending direction of the guide hole (200) is a shape formed by round-chamfering corner portions of a polygonal shape; and a probe (10) held by the probe head (20) in a state of penetrating the guide hole (200), wherein notches which go along an axial direction of the probe (10) are formed on angle regions of the probe (10), the angle regions facing the corner portions (200C) of the guide hole (200).

A contact probe for a testing head of an apparatus for testing electronic devices comprises a body extending along a longitudinal axis between a first end portion and a second end portion, the second end portion being adapted to contact pads of a device under test. Suitably, the contact probe comprises a first section, which extends along the longitudinal axis from the first end portion and is made of an electrically non-conductive material, and a second section, which extends along the longitudinal axis from the second end portion up to the first section, the second section being electrically conductive and extending over a distance less than 1000 m.

The present invention provides a guide plate for a probe card. The guide plate for the probe card according to the present invention includes: a first guide plate including a plurality of first pin insertion holes formed therein, and made of an anodic oxide film; and a second guide plate disposed to be spaced apart from the first guide plate by a predetermined distance, and including a plurality of second pin insertion holes through which probe pins passing through the first pin insertion holes pass, wherein a buffer part is provided at least partially on each of an upper portion and a lower portion of the first guide plate.

A probe card includes a conductive body, an insulation block, and a plurality of conductive microsprings. The insulation block covers at least one side of the body and at least partially encloses the microsprings. A first end of each microspring is connected to the conductive body and a second end is exposed from the insulation block. In operation, the probe card is moved onto one or more semiconductor devices to be tested. As the probe card is moved toward the semiconductor devices, the second ends of the conductive microsprings come into contact with contact pads on the semiconductor devices. The insulation block encloses the microsprings, which prevents the microsprings from buckling or making contact with each other. As a result, the probe card produces fewer false positives and false negatives during the testing process.

A probe card includes a printed circuit board (PCB), a connection substrate electrically connected with the PCB, a probe head, and a signal path switching module disposed on a lateral periphery surface or a bottom surface of the connection substrate, electrically connected with probe needles of the probe head and the connection substrate and including first and second circuit lines with first and second inductors respectively, and a capacitor electrically connected between the first and second circuit lines. A test signal from a tester is transmitted between the tester and a device under test (DUT) via the PCB, the connection substrate, the first and second circuit lines and the probe needles. A loopback test signal from the DUT is transmitted back to the DUT via the probe needles, parts of the first and second circuit lines and the capacitor.