A sensor intermediate part is provided with a physical quantity detection element that has a power source terminal, a ground terminal and an output terminal that outputs a desired output signal, where the physical quantity detection element is capable of adjusting properties of the output signal; a high-capacitance capacitor, which has at least a first terminal and a second terminal, and a jumper wire, one end of which is conducted to either the power source terminal or the second terminal and the other end of which is not conducted. The first terminal is conducted to the ground terminal, and the power source terminal and the second terminal are configured to be electrically connectable by the jumper wire.

A sensor intermediate part is provided with a physical quantity detection element that has a power source terminal, a ground terminal and an output terminal that outputs a desired output signal, where the physical quantity detection element is capable of adjusting properties of the output signal; a high-capacitance capacitor, which has at least a first terminal and a second terminal, and a jumper wire, one end of which is conducted to either the power source terminal or the second terminal and the other end of which is not conducted. The first terminal is conducted to the ground terminal, and the power source terminal and the second terminal are configured to be electrically connectable by the jumper wire.

Cantilever probes are produced for use in a test apparatus of integrated electronic circuits. The probes are configured to contact corresponding terminals of the electronic circuits to be tested during a test operation. The probe bodies are formed of electrically conductive materials. On a lower portion of each probe body that, in use, is directed to the respective terminal to be contacted, an electrically conductive contact region is formed having a first hardness value equal to or greater than 300 HV; each contact region and the respective probe body form the corresponding probe.

Cantilever probes are produced for use in a test apparatus of integrated electronic circuits. The probes are configured to contact corresponding terminals of the electronic circuits to be tested during a test operation. The probe bodies are formed of electrically conductive materials. On a lower portion of each probe body that, in use, is directed to the respective terminal to be contacted, an electrically conductive contact region is formed having a first hardness value equal to or greater than 300 HV; each contact region and the respective probe body form the corresponding probe.

A method of manufacturing a probe card for functionality testing of devices under test (DUT) is disclosed having the steps of providing an interface board configured for interfacing the probe card to a testing apparatus, providing a stiffener, connecting an interposer in the shape of a monobloc of material to the stiffener, cutting the monobloc according to a predetermined pattern after connecting it to the stiffener, thereby defining a plurality of modules which are independent and separated from each other, associating the interface board with the stiffener, and associating a probe head with the interposer. The probe head includes a plurality of contact elements adapted to electrically connect the interposer to contact pads of the devices under test. A probe card obtained by the method is also disclosed.

A method of manufacturing a probe card for functionality testing of devices under test (DUT) is disclosed having the steps of providing an interface board configured for interfacing the probe card to a testing apparatus, providing a stiffener, connecting an interposer in the shape of a monobloc of material to the stiffener, cutting the monobloc according to a predetermined pattern after connecting it to the stiffener, thereby defining a plurality of modules which are independent and separated from each other, associating the interface board with the stiffener, and associating a probe head with the interposer. The probe head includes a plurality of contact elements adapted to electrically connect the interposer to contact pads of the devices under test. A probe card obtained by the method is also disclosed.

A current sensor that can be downsized without lowering measurement precision has bus bars, magnetic sensors, each of which measures an induced magnetic field generated from one bus bar, a circuit board on which the magnetic sensors are mounted, a case that fixes the bus bars and circuit board, a lid that closes the case, and in-side magnetic shields provided in the lid. The in-side magnetic shield has cutouts along its circumferential edges. Hole are formed in the lid. From each hole, the outer edges of the cutout of the in-side magnetic shield are exposed. Therefore, when the lid is formed, the distance between adjacent in-side magnetic shields can be shortened when the in-side magnetic shield is positioned by pressing portions in a mold.

A probe card for testing of electronic devices comprises a testing head with plural contact probes inserted into guide holes of an upper guide and a lower guide, and a space transformer, each of the contact probes having a first terminal portion projecting from the lower guide with a first length and ending with a contact tip adapted to abut onto a respective contact pad of a device to be tested, and a second terminal portion projecting from the upper guide with a second length and ending with a contact head adapted to abut onto a contact pad of the space transformer. The probe card comprises a spacer element interposed between the space transformer and the upper guide and removable to adjust the first length of the first terminal portion by changing the second length of the second terminal portion and approaching the upper guide and the space transformer.

A probe card for testing of electronic devices comprises a testing head with plural contact probes inserted into guide holes of an upper guide and a lower guide, and a space transformer, each of the contact probes having a first terminal portion projecting from the lower guide with a first length and ending with a contact tip adapted to abut onto a respective contact pad of a device to be tested, and a second terminal portion projecting from the upper guide with a second length and ending with a contact head adapted to abut onto a contact pad of the space transformer. The probe card comprises a spacer element interposed between the space transformer and the upper guide and removable to adjust the first length of the first terminal portion by changing the second length of the second terminal portion and approaching the upper guide and the space transformer.

A method of treating a material on a probe is provided. The method includes the steps of immersing a probe tip into a first fluid, wherein the probe tip includes one or more oxidized metallic fragments on a surface of the probe tip; polarizing the probe tip, through a counter electrode, with a negative current to reduce the one or more oxidized metallic fragments to one or more substantially unoxidized metallic fragments; removing the probe tip from the first fluid; immersing the probe in a second fluid, wherein the second fluid is a complexer for the one or more substantially unoxidized metallic fragments; and polarizing the probe tip with a positive current, through the counter electrode, wherein the positive current oxidizes the one or more substantially unoxidized metallic fragments.