The disclosure relates to a method of fabricating a test socket including forming a plate-shaped first coupling block by joining a first base member made of a conductive material and a first insulating member made of an insulating material; forming a plate-shaped second coupling block by joining a second base member made of the conductive material and a second insulating member made of the insulating material; forming a first barrel accommodating hole for accommodating a part of the probe and a first support hole for supporting one end portion of the probe in the first coupling block; forming a second barrel accommodating hole for accommodating the rest of the probe and a first support hole for supporting the other end portion of the probe in the second coupling block; inserting one end of the probe into the first barrel accommodating hole to be supported on the first support hole, and inserting the other end of the probe into the second barrel accommodating hole to be supported on the second support hole; and joining the first coupling block and the second coupling block.

The present disclosure discloses a test socket including an inelastic insulating housing formed of an inelastic insulating material having a plurality of housing holes, and a plurality of electro-conductive parts comprising electro-conductive particles in an elastic insulating material, the electro-conductive parts including an electro-conductive part body having a lower end portion to be connected to a signal electrode of the tester, an upper end portion to be connected to the terminal of the device under inspection, and an electro-conductive part bump connected to the electro-conductive part body to protrude from one or both of an upper and lower surface of the inelastic insulating housing.

Disclosed is a test device for testing a high-frequency and high-speed semiconductor. The test device includes a probe supporting block formed with a tube accommodating portion along a test direction; a conductive shield tube accommodated in the tube accommodating portion; and a probe accommodated and supported in the shield tube without contact, the tube accommodating portion including a conductive contact portion for transmitting a ground signal to the shield tube. When a high-frequency and high-speed semiconductor or the like subject is tested, the test device easily and inexpensively prevents crosstalk between the adjacent signal probes and improves impedance characteristic.

A test apparatus and method for testing a semiconductor device. The semiconductor device includes an integrated circuit and a plurality of external radiating elements located at a surface of the device. The external radiating elements include at least one transmit element and receive element. The test apparatus includes a plunger. The plunger includes a dielectric portion having a surface for placing against the surface of the device. The plunger also includes at least one waveguide. Each waveguide extends through the plunger for routing electromagnetic radiation transmitted by one of the transmit elements of the device to one of the receive elements of the device. Each waveguide comprises a plurality of waveguide openings for coupling electromagnetically to corresponding radiating elements of the device. The dielectric portion is configured to provide a matched interface for the electromagnetic coupling of the waveguide openings to the plurality of external radiating elements of the device.

A testing device for testing an integrated circuit package is provided, including a printed circuit board having a first surface, a second surface, and multiple conductive layers between the first and second surfaces. A metal layer is formed on the second surface and is electrically connected to one of the conductive layers that is grounded. A testing socket is disposed over the first surface. A conductive fastener secures the testing socket to the printed circuit board and is electrically connected to the metal layer. A cover is disposed over the testing socket to form a space for accommodating the integrated circuit package between the cover and the testing socket. The cover has a conductive surface in contact with the integrated circuit package. A conductive element assembly is disposed between the cover and the testing socket and is electrically connected to the conductive surface and the conductive fastener.

A test socket assembly includes a contactor body having one or more compliant interconnects, and a socket opening sized and configured to receive a device under test therein. The test socket assembly further includes a lead frame assembly disposed within the contactor body and electrically coupled with the one or more compliant interconnects, and one or more antennas at least partially disposed within the contactor body, the one or more antennas configured to directly and wirelessly communicate to the device under test when the device is disposed within the socket opening.

A test kit for testing a device under test (DUT) includes a socket structure for containing the DUT. The DUT includes an antenna and radiates a RF signal. The test kit further includes a reflector having a lower surface. The RF signal emitted from the antenna of the DUT is reflected by the reflector and a reflected RF signal is received by the antenna of the DUT.

A testing socket includes a metal block, an assembly block, an analog ground probe pin and a digital ground probe pin. The metal block is formed with a concave portion and used to connect to an independent main ground. The assembly block is electrically isolated from the metal block, and detachably embedded in the recess, so that the metal block and the assembly block are assembled together to be a probe holder. The digital grounding probe is inserted in the metal block, electrically connected to the independent main ground through the metal block. The digital ground probe pin can be electrically connected to a device to be tested (DUT) and the independent main ground. The analog ground probe pin is inserted in the assembly block, and electrically connected to the DUT and another independent main ground.

An electrical ground connector for use as part of a test connector in an integrated circuit (IC) device testing apparatus having a resilient connector for electrical grounding and comprising a dual elastomer contact stacked vertically above a rigid ground block. The height of the ground block can be adjusted to compensate for the lack of height of the dual elastomer contacts, so that the entire connector has enough height to maintain electrical connection between a load board of the testing apparatus and the IC device.

A socket electrically connects a first electric component and a second electric component, including: a base part in which a through hole extending through the base part from a top surface to a bottom surface in a vertical direction is formed; a contact pin inserted to the through hole such that a pin lower end is exposed from the bottom surface, and configured such that, when in use, a pin upper end makes contact with the first electric component; and a sheet member including a through electrode extending therethrough in the vertical direction, disposed at the base part in a state where the sheet member faces the bottom surface, and configured such that, when in use, an upper end of the through electrode makes contact with the pin lower end and a lower end of the through electrode makes contact with the second electric component.