A testing apparatus includes a chip carrying device and a pressing device. The chip carrying device includes a circuit board and a plurality of electrically connecting units that are disposed on the circuit board and each can receive a chip. The pressing device includes a cover and an abutting member disposed between the cover and the electrically connecting units. The cover is disposed on the circuit board to jointly define an accommodating space that accommodates the abutting member and the electrically connecting units. The cover can be connected to an air suction apparatus for expelling air in the accommodating space. When the air suction apparatus performs a suction operation to expel the air in the accommodating space, the abutting member is abutted against the electrically connecting units and the chips so as to connect each of the electrically connecting units and the corresponding chip.

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.

An electrical contact assembly that uses an elastomer strip for each row of individual contacts. Each contact comprises a rigid bottom pin and a flexible top pin with a pair of arms which extend over and slide along sloped surfaces of the bottom contact. The elastomer strip is located between rows of the bottom and top pins. A bottom socket housing is provided with grooves which receive each elastomer strip. A row of top pins is then placed over each elastomer strip, and through ducts in the bottom socket housing. Bottom pins are then snapped into place in between the pair of arms.

The present invention relates to a test socket configured to electrically connect a tester generating a test signal and a device under inspection to each other includes a nonelastic electrically-conductive housing having a plurality of housing holes passing therethrough in a thickness direction, an insulating coating layer applied on at least an upper surface of the nonelastic electrically-conductive housing and a circumference of each of the plurality of housing hole, and an electrically-conductive part formed to have a configuration in which a plurality of electrically-conductive particles are contained in an elastic insulating material, disposed in the housing hole such that a lower end portion thereof may be connected to a signal electrode of the tester placed below the nonelastic electrically-conductive housing.

The present disclosure relates to a socket having a thin structure and to a spring contact suitable thereto. The socket includes: a plurality of spring contacts (100) each of which includes an upper contact pin (110), a lower contact pin (120) assembled to the upper contact pin such that the upper and lower contact pins cross each other to mutually linearly operate, and a coil spring (130) supporting the upper and lower contact pins (110 and 120); a lower film plate (310) including a plurality of first through-holes (311) through which the respective spring contacts (100) are positioned; an intermediate plate (320) provided on the lower film plate (310) and including second through-holes formed at positions corresponding to the first through-holes (311); and an upper film plate (330) provided on the intermediate plate (320) and including third through-holes formed at positions corresponding to the second through-holes.

Presented embodiments facilitate efficient and effective flexible implementation of different types of testing procedures in a test system. In one embodiment, a test system configuration adapter includes a tester side socket, a break out pin, and a device under test side slot. The tester side socket is configured to couple with a test equipment socket. The break out pin is configured to couple with the supplemental equipment. The device under test side slot is configured to couple with the tester side socket, the break out pin, and a device under test, wherein the tester side socket. The test system configuration adapter is configured to enable communication between test equipment coupled to the test equipment socket and supplemental equipment coupled to the breakout pin while the device under test remains coupled to the device under test side slot. In one exemplary implementation, the breakout pin and tester side socket are selectively coupled to the device under test side slot. The test system configuration adapter can include a switch configured to switch a portion of the coupling of the device under test side slot to the tester side socket and the break out pin.

An electrical contact assembly that uses an elastomer strip for each row of individual contacts. Each contact comprises a rigid bottom pin and a flexible top pin with a pair of arms which extend over and slide along sloped surfaces of the bottom contact. The elastomer strip is located between rows of the bottom and top pins. A bottom socket housing is provided with grooves which receive each elastomer strip. A row of top pins is then placed over each elastomer strip, and through ducts in the bottom socket housing. Bottom pins are then snapped into place in between the pair of arms.

Disclosed are a testing unit, system, and method for testing and predicting failure of optical receivers. The testing unit and system are configured to apply different values of current, voltage, heat stress, and illumination load on the optical receivers during testing. The test methods are designed to check dark current, photo current, forward voltage, and drift over time of these parameters.

A method of testing an integrated circuit of a device is described. Air is allowed through a fluid line to modify a size of a volume defined between the first and second components of an actuator to move a contactor support structure relative to the apparatus and urge terminals on the contactor support structure against contacts on the device. Air is automatically released from the fluid line through a pressure relief valve when a pressure of the air in the fluid line reaches a predetermined value. The holder is moved relative to the apparatus frame to disengage the terminals from the contacts while maintaining the first and second components of the actuator in a substantially stationary relationship with one another. A connecting arrangement is provided including first and second connecting pieces with complementary interengaging formations that restricts movement of the contactor substrate relative to the distribution board substrate in a tangential direction.

A test socket and a test apparatus for testing a semiconductor package are provided. The test socket includes: a first connection structure including a first insulating body and a plurality of conductive plugs within the first insulating body; and a second connection structure disposed on the first connection structure and including a second insulating body and a plurality of elastic conductive pillars, the second insulating body being elastic, and the plurality of elastic conductive pillars being formed by arranging a plurality of conductive particles in the second insulating body in a vertical direction; wherein the plurality of elastic conductive pillars are in vertical alignment with the plurality of plugs of the first connection structure, respectively, and the conductive particles in each of the plurality of elastic conductive pillars can produce electrical conductivity in response to an external pressure applied onto the elastic conductive pillar.