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.

A probe card for a test equipment of electronic devices includes a flexible membrane configured to carry high frequency signals between a device under test and a support plate. The flexible membrane is connected to the support plate through a peripheral zone, and a damping structure is arranged between the support plate and the flexible membrane. A plurality of micro contact probes include a body extending between a first end and a second end, and the second end is configured to abut onto contact pads of the device under test, and the damping structure and the first ends of the micro contact probes are in contact with opposite faces of a same contact zone of the flexible membrane. The flexible membrane includes at least one weakening zone arranged between the contact zone and the peripheral zone.

A probe card for testing a device under test having a plurality of contact pads includes a support plate having first contact pads thereon. A flexible membrane has a first face and a peripheral portion including second contact pads thereon. A plurality of contact probes are associated with a first face of the flexible membrane and are configured to abut onto the plurality of contact pads of the device under test. A sliding contact area includes: the first contact pads formed on the support plate; the second contact pads formed on the peripheral portion of the flexible membrane, the peripheral portion of the flexible membrane configured to come in pressing contact onto the support plate at the sliding contact area. A pressing element contacts the peripheral portion of the flexible membrane at the sliding contact area, and the pressing element puts the second contact pads into pressing contact with the first contact pads.

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.

A novel modular probe may include an interchangeable (connectable/disconnectable) probe-tip adaptor having a tip connector for coupling to a device under test, and further having a probe-tip terminal for coupling to a first assembly connector of a cable assembly, which further has a second assembly connector for coupling to a first build-out terminal of a build-out adaptor, which also has a second build-out terminal for coupling to an assembly connector of an interchangeable instrument connector cable assembly, which also has an instrument-end connector for coupling to a measurement instrument. The built-out adaptor may include a compensation adjustment circuit for compensating the probe for varying system capacitances. The probe may include one or more corrective circuits in the interchangeable probe-tip adaptor and/or in the build-out adaptor for at least partially terminating each end of the cable assembly with a characteristic impedance of the cable in the cable assembly to attenuate reflections.

A cantilever-type probe with multiple metallic coatings is disclosed. The cantilever-type probe includes at least one probe pin. A first metallic coating is disposed upon a tip of the probe pin, and a second metallic coating is disposed upon a root of the probe pin. The second metallic coating is in contact with the first metallic coating and comprises a softer (more flexible) metal than the first metallic coating.

Systems, methods, and a computer readable medium are provided herein for providing an indication of a connection terminal on a measurement device for use in performing a test of a target device. The system can include a target device and a measurement device. The measurement device can couple to the target device via a plurality of connection terminals to perform a test of the target device. The measurement device can receive an input identifying a test to be performed on the target device by the measurement device. The measurement device can determine, based on the received input, an indication identifying at least one connection terminal of the plurality of connection terminals to connect to the target device to perform the test. The measurement device can provide the indication of the at least one connection terminal via an indication mechanism associated with the at least one connection terminal.

The present disclosure relates to a radio frequency (RF) functional probe for testing an RF device in a cryogenic environment. The RF functional probe includes a probe head configured to receive the RF device, a flange structure, an isolation structure coupled between the probe head and the flange structure, and an RF cable structure extending from the flange structure, through the isolation structure, and to the probe head. The isolation structure is configured to provide thermal and electrical isolation to reduce radiant heat leak from the RF cable structure to the RF device. Herein, the isolation structure includes multiple baffle structures, each of which includes cable guides. The cable guides of each baffle structure are configured to guide routing paths for the RF cable structure. The RF cable structure is configured to transmit signals to and from the RF device.

The test socket includes a fifth housing 15 located in a central part of contact terminals 21 in an axial direction and having electrical conductivity, plural through-holes 15c being formed in the fifth housing 15 to pass the respective contact terminals 21 therethrough; a sixth housing 16 stacked in the axial direction on the fifth housing 15, passage holes being formed in the sixth housing 16, the passage holes being configured to position the contact terminals 21 in a direction orthogonal to the axial direction; and an eighth housing 18 having electrical conductivity and stacked in the axial direction by sandwiching the sixth housing 16 between the eighth housing 18 and fifth housing 15, wherein the sixth housing 16 is provided with through-vias configured to form a conductive path in the axial direction.

Methods, systems, and apparatus for an electrical connector assembly for connecting an integrated circuit chip to a printed circuit board. The electrical connector assembly includes a socket body that is made of an insulating material. The socket body has a top surface, a bottom surface, and a first plurality of cavities including a first cavity and a second cavity. The first cavity and the second cavity each have an inner surface plated with a conductive material to form a metal grounding shell. The electrical connector assembly includes multiple probes including a first probe and a second probe. The first probe is configured to be positioned within the first cavity and the second probe is configured to be positioned within the second cavity. The electrical connector assembly includes one or more signal traces that electrically connect the metal grounding shells of the first cavity and the second cavity.