An electrical characterization and fault isolation probe can include a cable, a connector, and a coating over a portion of the cable. The cable can have a first conductor having a first impedance, a second conductor having a second impedance, and a dielectric surrounding the first conductor and electrically isolating the first conductor from the second conductor. The connector can physically couple to, and be in electrical communication with, the cable. The connector can include a first electrical communication pathway and a second electrical communication pathway. The first electrical communication pathway can be electrically isolated from the second electrical communication pathway. The first electrical communication pathway can be in electrical communication with the first conductor. The second electrical communication pathway can be in electrical communication with the second conductor. The connector can have a fifth impedance.

A probe unit includes: first contact probes each coming into contact with a target electrode on one end side in a longitudinal direction; a second contact probe connected to an external ground; a signal pipe disposed around each first contact probes; a ground member provided around each signal pipe and configured to form an air layer with the signal pipe; a probe holder including a plate-shaped first and second members; a first wiring part provided at least on a front surface of the first member and electrically connected to the second contact probe; a second wiring part provided at least on a front surface of the second member and electrically connected to the second contact probe; a first conductive unit configured to electrically connect the first wiring part and the ground member; and a second conductive unit configured to electrically connect the second wiring part and the ground member.

A high-frequency testing probe is disclosed. The probe includes a layered probe substrate having a first and second PCB, as well as first and second conducting traces disposed on opposite sides of the substrate. The probe substrate has an ungrounded differential region including two probe tips coupled to the traces, a grounded differential region, and a decoupled differential region including two probe connectors coupled to the traces. The probe also includes a ground plane between the two PCBs and between the two traces in the decoupled and grounded differential regions. In the ungrounded differential region, the first and second traces form a first differential transmission pair having a differential impedance. In the grounded differential region, the first and second traces form a second differential transmission pair having the differential impedance. The probe connectors are configured to couple to one of a vector network analyzer and a time domain reflectometer.

A radio frequency sensor system comprising a housing defining a resonant cavity. Radio frequency probe(s) in the cavity transmit and/or receive radio frequency signals. A radio frequency control unit is in communication with the radio frequency probe(s) for determining one or more states of the radio frequency sensor system based on changes in the characteristics of the radio frequency signals. A machine learning system is in communication with the radio frequency control unit for identifying and developing transfer functions and calibrations based on the changes in the characteristics of the radio frequency signals and determining the one or more states of the radio frequency sensor system.

The invention relates to a probe card (PC) for use with an automatic test equipment (ATE), wherein the probe card (PC) comprises a probe head (PH) on a first side thereof, and wherein the probe card (PC) is adapted to be attached to an interface (IF) and wherein the probe card (PC) comprises a plurality of contact pads on a second side in a region opposing at least a region of the interface (IF), arranged to contact a plurality of contacts of the interface (IF), and wherein the probe card (PC) comprises one or more coaxial connectors (CCPT) arranged to mate with one or more corresponding coaxial connectors (CCPT) of the interface (IF). The invention relates further to pogo tower (PT) for connecting a wafer probe interface (WPI) of an automatic test equipment with the probe card (PC).

A probe unit includes: first contact probes each coming into contact with a target electrode on one end side in a longitudinal direction; a second contact probe connected to an external ground; a signal pipe disposed around each first contact probes; a ground member provided around each signal pipe and configured to form an air layer with the signal pipe; a probe holder including a plate-shaped first and second members; a first wiring part provided at least on a front surface of the first member and electrically connected to the second contact probe; a second wiring part provided at least on a front surface of the second member and electrically connected to the second contact probe; a first conductive unit configured to electrically connect the first wiring part and the ground member; and a second conductive unit configured to electrically connect the second wiring part and the ground member.

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 testing head apt to verify the operation of a device under test integrated on a semiconductor wafer includes a plurality of contact elements, each including a body that extends between a first end portion and a second end portion, and a guide provided with a plurality of guide holes apt to house the contact elements. The guide includes a conductive portion that includes and electrically connects the holes of a group of guide holes to each other and is apt to contact a corresponding group of contact elements apt to carry a same type of signal.

The invention relates to a high-frequency test connector device (12; 12′) having an adapter housing including a sleeve-like ground contact section (10; 10′) axially at one end, (18) at the other end, and centrally an insulated inner contact (20), wherein the ground contact section has an electrically conducting spring member (26; 26′, 28; 42, 44; 44′, 46) for ground contact, associated such that for engaging over the sleeve section (14) of the contacting partner (16), the latter with an end face (30), to form a contact and resiliently along the movement or connecting longitudinal axis, can engage on the spring member (26) formed in a sleeve base of the ground contact section (10), or wherein, for engaging in the sleeve section (14′) of the connecting partner (16′), the spring member (26′) projects from an end face end section of the ground contact section (10′), to form a contact and resiliently along the longitudinal axis, can engage on a ground-conducting inner section (40) of the connecting partner.

A test device for a high-speed/high-frequency test. The test device includes: a conductive block which includes a probe hole; at least one signal probe which is supported in an inner wall of the probe hole without contact, includes a first end to be in contact with a testing contact point of the object to be tested, and is retractable in a lengthwise direction; and a coaxial cable which includes a core wire to be in electric contact with a second end of the signal probe. With this test device, the coaxial cable is in direct contact with the signal probe, thereby fully blocking out noise in a test circuit board.