The present disclosure provides a probe cable assembly comprising a probe interface configured to couple to a measurement interface and to receive a differential signal, a measurement output interface configured to output the differential signal, and a cable arrangement electrically arranged between the probe interface and the measurement output interface and configured to conduct the differential signal between the probe interface and the measurement output interface, the cable arrangement comprising a cable, a plurality of magnetic elements arranged around at least a section of the length of the cable, wherein each magnetic element is separated by a gap from adjacent magnetic elements, and a plastically deformable guiding element configured to fix the cable arrangement with a predetermined relative position between the probe interface and the measurement output interface.

The present disclosure relates to a coaxial lead structure and method for radiating a GIS partial discharge UHF signal outward. The structure includes a GIS cavity, a circular hole provided on the GIS cavity, a medium cylinder provided at the circular hole and sealing the circular hole, a thin cylindrical metal lead that extends into and is fixed to the medium cylinder, and a ground lead connected to the thin cylindrical metal lead. According to the present disclosure, a relatively strong signal may be obtained outside a coaxial lead structure, and detection of a partial discharge UHF signal at this position may increase the detection sensitivity by one time compared with the detection methods of built-in and external disc insulators.

A high-frequency coaxial attenuator includes a first coaxial cable portion that includes a first center conductor having a first length, and a first insulator of the first length formed around the first center conductor, wherein the first center conductor and the first insulator form a first diameter. A second coaxial cable portion is separated from the first coaxial cable portion by a gap. The second coaxial cable portion includes a second center conductor having a second length, and a second insulator of the second length formed around the second center conductor. A semiconductor material is deposited in the gap between the first coaxial cable portion and the second coaxial cable portion. The semiconductor material may be configured to provide an impedance of 500Ω and provides 20 dB of attenuation, and a 10:1 voltage divider based on a 50Ω input impedance of test equipment.

A high-frequency testing probe with a probe substrate and at least two probe tips. The probe substrate is a printed circuit board and the probe tips are coupled to and extend away from the printed circuit board. The first and second probe tips are each communicatively coupled to respective first and second probe connectors through respective first and second conducting traces disposed upon respective first and second sides of the printed circuit board. The probe connectors are configured to couple the testing probe to at least one of a high-frequency vector network analyzer and a high-frequency time domain reflectometer. The positions of the first ends of the first and second probe tips are adjustable. The first and second probe tips may be coupled to the first and second conducting traces through respective first and second joints, and may be configured to rotate about the first and second joints.

End launch termination devices are shown and disclosed. In one embodiment, the device includes a housing, a first clamp fixedly attached to the housing, and a second clamp opposed to the first clamp and movably attached to at least one of the first clamp or the housing, the first and second clamps defining a gap therebetween to receive a test substrate. The device additionally includes a conductor received in the cavity and fixedly attached to the housing, a center pin attached to the conductor and extending into the gap, and a rod resistor received in the cavity, attached to the conductor, and extending out of the housing.

A high-frequency testing probe having a probe substrate and at least two probe tips. The probe substrate is a printed circuit board and the probe tips are coupled to and extend outward from the printed circuit board. The first and second probe tips are each communicatively coupled to respective first and second probe connectors through respective first and second conducting traces disposed upon the printed circuit board. The probe connectors are configured to couple the testing probe to at least one of a high-frequency vector network analyzer and a high-frequency time domain reflectometer. The probe tips translate along their respective central longitudinal axes through respective adjustable couplings to modify respective distances the probe tips extend outward from the printed circuit board.

A system may include a printed circuit board with a microstrip and a conductive structure surrounding the microstrip. The system may include a probe lead in communication with the conductive structure. The system may include a first contact pad electrically connected to the conductive structure and a second contact pad electrically connected to the conductive structure.

An elastic probe element, an elastic probe assembly, and a testing device are provided. The testing device includes a substrate, a guiding member, and multiple ones of the elastic probe elements. The guiding member has a plurality of through holes for the multiple ones of the elastic probe elements correspondingly passing through. The elastic probe element includes a main body, a first contact segment, and a second contact segment that are integrally formed. The main body has a plurality of needle structures, and any two adjacent needle structures have a gap arranged therebetween. The needle structures are connected to each other through a first connection part and a second connection part arranged at a first end and a second end of the elastic probe element, respectively. The first contact segment is arranged at the first end. The second contact segment is arranged at the second end.

It is possible to make the free length of a contactor uniform even when the contactor is joined to a position that deviates from a joint position in a high-frequency conducting path and make contact with an electrode with stability, which improves measurement quality. A probe unit according to the present disclosure includes: a coaxial connector that is attached to a main body and gives and receives an electrical signal to and from a tester via a coaxial cable; a high-frequency conducting path that is connected to the coaxial connector and transmits an electrical signal; a plurality of contactors, each having a tip portion that makes electrical contact with an electrode of an object to be inspected and giving and receiving an electrical signal to and from the high-frequency conducting path; and a pedestal that is interposed between the contactor and the high-frequency conducting path, and the pedestal is provided in each contactor such that a free length of the contactor is a predetermined length.

A high-frequency coaxial attenuator includes a first coaxial cable portion that includes a first center conductor having a first length, and a first insulator of the first length formed around the first center conductor, wherein the first center conductor and the first insulator form a first diameter. A second coaxial cable portion is separated from the first coaxial cable portion by a gap. The second coaxial cable portion includes a second center conductor having a second length, and a second insulator of the second length formed around the second center conductor. A semiconductor material is deposited in the gap between the first coaxial cable portion and the second coaxial cable portion. The semiconductor material may be configured to provide an impedance of 500Ω and provides 20 dB of attenuation, and a 10:1 voltage divider based on a 50Ω input impedance of test equipment.