A method of making a cantilever MEMS probe module includes the steps of forming a cantilever MEMS probe on a first surface of a circuit substrate by a MEMS fabrication process in a way that the cantilever MEMS probe has a support post electrically and mechanically connected with an electric contact of the first surface, a cantilever arm connected with the support post, and a needle connected with the cantilever arm, and forming a through hole penetrating through the first surface and a second surface opposite to the first surface of the circuit substrate and corresponding in position to the needle and a part of the cantilever arm by using a cutting tool to cut the circuit substrate from the second surface toward the first surface of the circuit substrate. A probe module made by the method is disclosed too.

The present invention relates to a method for manufacturing a sensor for a thermal, flow measuring device and a sensor. The method includes, in such case, manufacturing a metal jacketing for a sensor core, introducing the sensor core into the metal jacketing and sintering the metal jacketing with introduced sensor core.

A probe head comprises a plate-shaped support including respective pluralities of guide holes, a plurality of contact probes being slidingly housed in the respective pluralities of guide holes and including at least a first group of contact probes being apt to carry only one type of signal chosen between ground and power supply signals, a conductive portion realized on the support and including a plurality of the guide holes housing the contact probes of the first group, and at least one filtering capacitor having at least one capacitor plate being electrically connected to the conductive portion, the conductive portion electrically connecting the contact probes of the first group.

A probe head comprises a plate-shaped support including respective pluralities of guide holes, a plurality of contact probes being slidingly housed in the respective pluralities of guide holes and including at least a first group of contact probes being apt to carry only one type of signal chosen between ground and power supply signals, a conductive portion realized on the support and including a plurality of the guide holes housing the contact probes of the first group, and at least one filtering capacitor having at least one capacitor plate being electrically connected to the conductive portion, the conductive portion electrically connecting the contact probes of the first group.

A system and method for disassembling a multiple contact probe head including a plurality of contact probes positioned by a first die at a first end of the plurality of probes and a second die at a second end of the plurality of probes, are provided. The system may include a manifold configured to sealingly receive an opposing side of the first die from the second die; and a vacuum source operatively coupled to the manifold to apply a vacuum to an interior of the manifold applying a force to the plurality of contact probes in position in the first die across. Where the probes include a paramagnetic material, a magnetic source may be employed to hold the probes during disassembly.

A system and method for disassembling a multiple contact probe head including a plurality of contact probes positioned by a first die at a first end of the plurality of probes and a second die at a second end of the plurality of probes, are provided. The system may include a manifold configured to sealingly receive an opposing side of the first die from the second die; and a vacuum source operatively coupled to the manifold to apply a vacuum to an interior of the manifold applying a force to the plurality of contact probes in position in the first die across. Where the probes include a paramagnetic material, a magnetic source may be employed to hold the probes during disassembly.

A test circuit, a test method, an array substrate and a manufacturing method thereof are provided. The test circuit includes a plurality of to-be-tested units and plurality of test electrodes connected to the to-be-tested units. The plurality of to-be-tested units are arranged in a matrix. At least one of the test electrodes is multiplexed by the plurality of to-be-tested units in a row direction and at least one of the test electrodes is multiplexed by the plurality of to-be-tested units in a column direction.

A contact probe comprises a probe body being 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. Suitably, the end portion comprises at least one indentation adapted to house a material scrap being on the contact probe after a separation from a substrate wherein the contact probe has been realized.

A skate on a tip of a probe for testing electrical devices is a reduced thickness probe tip contact. Such a skate can advantageously increase contact pressure, but it can also undesirably reduce probe lifetime due to rapid mechanical wear of the skate. Here multilayer skate probes are provided where the overall shape of the probe tip is a smooth curved surface, as opposed to the conventional fin-like skate configuration. The skate layer is the most mechanically wear-resistant layer in the structure, so abrasive processing of the probe tip leads to a probe skate defined by the skate layer. The resulting probes provide the advantage of increased contact pressure without the disadvantage of reduced lifetime.

A skate on a tip of a probe for testing electrical devices is a reduced thickness probe tip contact. Such a skate can advantageously increase contact pressure, but it can also undesirably reduce probe lifetime due to rapid mechanical wear of the skate. Here multilayer skate probes are provided where the overall shape of the probe tip is a smooth curved surface, as opposed to the conventional fin-like skate configuration. The skate layer is the most mechanically wear-resistant layer in the structure, so abrasive processing of the probe tip leads to a probe skate defined by the skate layer. The resulting probes provide the advantage of increased contact pressure without the disadvantage of reduced lifetime.