A high-speed circuit assembly includes a high-speed circuit including at least one waveguide/transmission line, and a radiation absorbing material disposed in contact with or in close proximity with the waveguide/transmission line.

A test probe assembly includes: a conductive pipe; a probe inserted in the pipe without contacts and elastically retractable along a lengthwise direction; and an insulation probe supporting member configured to support the probe between an inner wall of the pipe and an outer surface of the probe. The test probe assembly of the present disclosure is improved in noise shield performance and convenient in repairing the probe since the probe is mounted to a probe socket as supported in a metal pipe without contacts.

An improved method and structure for forming an electrical interconnects mechanism in a Power Distribution Network (PDN) by placing capacitors on the top of the pin array on the printed circuit board (PCB) of the structure to decouple the PDN and results in lower impedance benefitting the frequency range of the PDN effecting a significant performance improvement in the spring-pin inductance from the transmission line. This reduction in impedance reduces the power supply ripple.

The present invention provides a novel method of constructing a coax spring-pin socket that furnishes better performance and is easier to manufacture in volume using common dielectrics and copper plating. This is accomplished by, in application, a lamination of PCB dielectric layers. This dielectric block is then drilled, plated, etched, and drilled in steps for the construction of a coaxial structure for the signal pins, and a ground structure for ground pins. This design process that can be quickly adjusted and customized for each design.

Provided are a socket for a semiconductor chip test, and a method of manufacturing the same, the socket for the semiconductor chip test including: a film layer; a semiconductor chip test terminal disposed on the film layer and connected to a terminal of a semiconductor chip; and a conductive elastic pad disposed on the film layer and connected to a ground terminal of the semiconductor chip.

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.

A test fixture includes a signal test board, a circuit routing, and a branch routing. The signal test board includes a first surface and a second surface. The first surface has a first pin and a test point. The second surface has a second pin. The circuit routing is located in the signal test board and configured to connect the first pin and a corresponding second pin. A portion of the circuit routing includes an upper routing connected with one first pin, a lower routing connected with one second pin, and a via-hole routing connected with two ends of the upper routing and the lower routing. One end, connected with the via-hole routing, of the upper routing is located in a projection area of the corresponding test point. The branch routing is located in the signal test board and configured to connect the test point with a corresponding upper routing.

Devices for testing a DUT having a circuit coupled to an antenna are disclose. The device can include a DUT location for receiving a DUT, and an adapter or probe is used to wirelessly “over-the-air” (OTA) electronically test a DUT with an embedded antenna or antenna array with the measurement probe 140 located in close proximity to the DUT. The probe can be located very close to the DUT (e.g., in the near-field region). Although the probe is located in close proximity to the DUT antenna or antenna array elements it does not significantly disturb or interfere with probe during testing.

A structure for signal transmission is disclosed. The structure comprises a first plurality of waveguides tightly disposed together and disposed substantially in parallel with each other, each of said waveguides having a first opening and a second opening, wherein each first opening is operable to align with a patch antenna, and wherein the first plurality of waveguides is disposed adjacent to a socket. The integrated structure further comprises the socket which comprises an opening operable to support an insertion of a device under test (DUT), wherein the DUT is communicatively coupled to a plurality of microstrip transmission lines on a printed circuit board (PCB) underlying the socket for transmitting test signals from the DUT, wherein each of the microstrip transmission lines is electrically coupled to a respective patch antenna. Further, the first plurality of waveguides and the socket are integrated into a single plastic or metal structure.

Embodiments of the present disclosure use customizable waveguides that can be positioned next to each other in a structure that contains one single flange to provide a physical connection for the waveguides. In this fashion, many waveguides can be positioned within a small area to accommodate a tightly packed patch antenna array so that the waveguides can be positioned very close to the socket. As such, embodiments of the present disclosure allow more waveguides to be packed into a small area by providing a single structure that houses many waveguides and share only a single flange connection element that can be sized appropriately.