A contactor for connection and signal transfer between conductors includes: a core part configured to extend in a longitudinal direction, contain a conductive particle and be formed to be elastically deformable; an insulation part configured to surround a transverse surface of the core part and be formed to be elastically deformable; and a shield part configured to surround a transverse surface of the insulation part to be spaced apart from the core part, contain a conductive particle and be formed to be elastically deformable.

A first signal line pattern has one end electrically connected to a first connector. A second signal line pattern has one end electrically connected to a second connector. The second signal line pattern has the other end facing the other end of the first signal line pattern. A conductive block has a convex portion. The convex portion of the conductive block is electrically connected to a third portion of the conductive pattern positioned between the other end of the first signal line pattern and the other end of the second signal line pattern of the wiring board.

The socket 20 comprises a first contact probe 21 which has a first end which is to contact with a first terminal 91 of the DUT 90, a second contact probe 22 which has a second end which is to contact with a second terminal 92 of the DUT 90, and an inner housing 23 which holds the first and second contact probes 21, 22 so that the first end and the second end are located on substantially the same virtual plane VP, and the length L.sub.2 of the second contact probe 22 is shorter than the length L.sub.1 of the first contact probe 21. The interposer 30 comprises a substrate 31 which has a through hole 311 into which the first contact probe 21 is to be inserted, and a wiring pattern 32 which is disposed on the substrate 31, and the wiring pattern 32 has a pad 321 with which the second contact probe 22 is to contact.

A method of testing sensors includes providing a test sheet that includes a plurality of sensor assemblies, a plurality of test pads, and traces extending from the sensor assemblies to the plurality of test pads. A sensor is positioned on each sensor assembly. Each sensor is connected to the sensor assembly with wire bonds. An enclosure is formed over the plurality of sensor assemblies. An electrical signal is detected from each of the plurality of sensor assemblies at the test pads.

A power meter includes a power meter housing and a terminal block that is movable relative to the power meter housing between a first orientation where two or more terminals of the terminal block face a first direction, and a second orientation where the two or more terminals of the terminal block face a second direction. A controller is operatively coupled to the two or more terminals of the terminal block in the first orientation and in the second orientation and is configured to determine a number of power monitor parameters for one or more phases of power that is delivered to a load based at least in part on signals at the two or more terminals of the terminal block.

There is described a method for testing equipment using a test box unit and a mate-in interface having a unique mate-in interface ID, the equipment comprising a plurality of contacts. The method comprises connecting a mate-in interface to the test box unit, connecting the mate-in interface to the contacts of the equipment; selecting a mate-in interface for testing using the unique mate-in interface ID; in the mate-in interface as selected, selecting any one of the contacts for testing; and testing the any one of the contacts of the selected mate-in interface to ground and against each other one of the contacts by inputting a signal and measuring the signal through the selected mate-in interface. There can then be automatically created a list of connections for the equipment making use of the detected or otherwise obtained unique mate-in interface ID.

A mobile transformer test device (10) for testing a power transformer (40) has connectors (12) for the detachable connection of the transformer test device (10) to the power transformer (40). The transformer test device (10) has a source (5) for generating a test signal. The mobile transformer test device (10) has an evaluation circuit (6) for determining, based on the test signal and a test response of the power transformer (40), information regarding a B-H curve (50, 60) of the power transformer (40).

A probe card testing device includes a testing circuit board, a signal transmission board, an electrical connecting module, and a probe head. The testing circuit board has metal pads spaced apart from each other. The signal transmission board has internal pads arranged on a bottom surface thereof and spaced apart from each other. The electrical connecting module includes a spacer having thru-holes and elastic arms positioned on the spacer. The spacer is sandwiched between the testing circuit board and the signal transmission board. The metal pads respectively face the internal pads through the thru-holes. A part of each elastic arm is arranged in one of the thru-holes, and is detachably compressed by one of the metal pads and the corresponding internal pad so as to be elastically deformed to establish an electrical transmission path. The probe head is disposed on a top surface of the signal transmission board.

An electrical connector with extension terminals includes an insulating housing, a movable terminal, a spring and a conductive reed terminal. The insulating housing has terminal axial holes each having a ridge. The insulating housing has reed sockets arranged around and communicated with the terminal axial holes. The movable terminal accommodates therein a spring. The movable terminal has a groove. The movable terminal is such inserted into the terminal axial hole of the insulating housing that the groove fittingly receives the ridge, thereby limiting the movable terminal to move in the terminal axial hole but preventing the movable terminal from leaving from and rotating in the terminal axial hole. The conductive reed terminal has inserts and a weld leg. The insert has a reed. When the insert is inserted into the reed socket, the reed abuts against the movable terminal, thereby establishing conductivity therebetween.

A sensor detects a detected value for a covered wire without metallic contact, and includes: a tubular support that has a male thread and an insertion channel in which the covered wire is inserted and supported; a tubular shell that is inserted into the support from a base end; a pillar-shaped detection electrode that is inserted in and supported by the shell; and a tubular threaded piece that screws onto the male thread, is rotatably attached onto the shell, and is moved, along the axis of the support, together with the shell and the detection electrode by a screwing operation. The detection electrode is configured so that the front surface is pressed onto the covered wire in the support when the detection electrode moves, resulting in the front surface becoming capacitively coupled to a core wire of the covered wire via an insulating covering.