Disclosed is a test device for testing an electric characteristic of an object to be tested. The test device includes a block comprising a probe hole, a probe supported in the probe hole and retractably configured to connect a first contact point and a second contact point, and a coaxial cable comprising an insulated sheath, a main core surrounded with the insulated sheath, and a probe contact portion exposed from the insulated sheath and extended from the main core so as to be in contact with the probe. An axis of the probe is spaced apart from an axis of the coaxial cable, and the probe contact portion is extended from the main core toward the axis of the probe.

This electrical connection socket for relaying exchange of electrical signals between a first electrical component and a second electrical component, is provided with: a signal pin which is inserted in a communication hole of a metallic casing so as to form a coaxial line path between the inner wall surface of the communication hole and the outer circumferential surface of the signal pin so that one end of the signal pin is electrically connected to a terminal of the first electrical component while the other end is electrically connected to a terminal of the second electrical component; and a holding member which holds the signal pin in the communication hole such that the outer circumferential surface of the signal pin is separated from the inner wall surface of the communication hole, wherein the characteristic impedance of a signal path formed by the signal pin in a first region where the signal pin is held by the holding member is smaller than a predetermined characteristic impedance which is a reference, and the characteristic impedance in a second region adjacent to the first region is larger than the predetermined characteristic impedance.

The socket 20 comprises a first contact probe 21 which has a first end which is to contact with a first terminal 91 of the DUT 90, a second contact probe 22 which has a second end which is to contact with a second terminal 92 of the DUT 90, and an inner housing 23 which holds the first and second contact probes 21, 22 so that the first end and the second end are located on substantially the same virtual plane VP, and the length L.sub.2 of the second contact probe 22 is shorter than the length L.sub.1 of the first contact probe 21. The interposer 30 comprises a substrate 31 which has a through hole 311 into which the first contact probe 21 is to be inserted, and a wiring pattern 32 which is disposed on the substrate 31, and the wiring pattern 32 has a pad 321 with which the second contact probe 22 is to contact.

The inspection socket includes: a contact terminal 80 including a barrel 82 having a flange section 90, a device-side terminal 84, and a board-side terminal 86; housings 10, 30, and 50 having through holes 10c, 30c, and 50c into which the contact terminal 80 is inserted; and housings 20 and 40 having through holes 20c and 40c into which the contact terminal 80 is inserted, the through holes 20c and 40c being larger than the outer diameter of the contact terminal 80 excluding the flange section 90 and smaller than the outer diameter of the flange section 90. The housings 20 and 40 are sandwiched between the housings 10, 30, and 50, the flange section 90 is contained in the through hole 50c, and the through holes 10c, 30c, and 50c are designed to have, for impedance matching, a gap from the outer periphery of the contact terminal 80.

A testing apparatus comprises a tester comprising a plurality of racks, wherein each rack comprises a plurality of slots, wherein each slot comprises: (a) an interface board affixed in a slot of a rack, wherein the interface board comprises test circuitry and a plurality of sockets, each socket operable to receive a device under test (DUT); and (b) a carrier comprising an array of DUTs, wherein the carrier is operable to displace into the slot of the rack, and wherein each DUT in the array of DUTs aligns with a respective socket of the plurality of sockets on the interface board. The testing apparatus further comprises a pick-and-place mechanism for loading the array of DUTs into the carrier and an elevator for transporting the carrier to the slot of the rack.

An example test system includes packs. The packs include test sockets for testing devices under test (DUTs) and at least some test electronics for performing tests on the DUTs in the test sockets. Different packs are configured to have different configurations. The different configurations include at least different numbers of test sockets arranged at different pitches.

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.

This electrical connection socket for relaying exchange of electrical signals between a first electrical component and a second electrical component, is provided with: a metallic casing which has a communication hole for communication between the upper surface and lower surface of the metallic casing, to the lower surface side of which the first electrical component is attached, and to the upper surface of which the second electrical component is attached; a signal pin which is disposed in the communication hole so as to be separated from the inner wall surface of the communication hole, one end of which is electrically connected to a terminal of the first electrical component, and the other end of which is electrically connected to a terminal of the second electrical component; an annular first holding member which is, in the upper region of the communication hole, press-fitted in the communication hole; and an annular second holding member which is, in the lower region of the communication hole, press-fitted to the outer circumferential surface of the signal pin, wherein the signal pin is fixed in the communication hole so as to be held by the metallic casing from above and from below via the first and second holding members.

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 testing system and method for testing integrated circuits with radio frequency (RF) antennas is disclosed. The system includes an alignment plate for receiving a device under test (DUT) having an RF transmitting antenna, an enclosure surrounding but separated from the transmitting antenna, a receiving antenna in a telescopic enclosure, and a conversion circuit connected to the receiving antenna. The conversion circuit is configured to convert an RF output from the DUT to a direct current (DC) voltage. The DC voltage is used as a proxy for the RF output to test the DUT. When testing chips with RF ports, the chip or ports are surrounded by the enclosure which is non-radio reflective and includes antennas for receiving RF outputs disbursed around the enclosure, or a single antenna. If multiple receiving antennas are used, sequential testing can also detect directional transmission patterns to confirm that the direction is correctly calibrated.