A temperature adjusting device including a main body and a pressing component is provided. The main body includes a first main body thru-hole and a second main body thru-hole. The main body has a first fluid channel and a second fluid channel therein, the first fluid channel is in spatial communication with the first main body thru-hole, and the second fluid channel is in spatial communication with the second main body thru-hole. The pressing component partially protrudes from one side of the main body, the pressing component has a fluid accommodating slot therein that is in spatial communication with the first fluid channel and the second fluid channel. A fluid having a predetermined temperature can enter into the main body from the first main body thru-hole, enter into the fluid accommodating slot through the first fluid channel, and exit the main body through the second main body thru-hole.

A chip testing apparatus including a chip testing machine, a temperature testing device, and a lid is provided. The chip testing machine includes a substrate and a plurality of chip testing sockets. Each of the chip testing sockets is disposed on the substrate and configured to carry a chip under test. The temperature adjusting device is disposed on the chip testing machine, and the lid covers the temperature adjusting device and the chip testing sockets. The temperature adjusting device includes a main body and a plurality of pressing components. The main body includes a plurality of fluid channels, and each of the pressing components can press one side of one of the chips under test. A fluid can flow into one of the fluid channels and flow through the pressing components, so that the chips under test are in an environment having a predetermined temperature.

A burn-in board management system includes a production burn-in apparatus and a burn-in board status computer. The production burn-in apparatus is configured to test a plurality of integrated circuit devices mounted in slots of a burn-in board and comprising a first controller configured to generate a first burn-in board status map, wherein the first controller is further configured to suspend the burn-in board when the first burn-in board status map of the burn-in board demonstrates that more than a threshold percentage of the slots of the burn-in board are determined to be malfunctioned. The burn-in board status computer is communicably connected with the first controller of the production burn-in apparatus and configured to receive the first burn-in board status map.

A test carrier that accommodates a DUT and includes a first flow passage through which fluid supplied from an outside of the test carrier flows.

An optical probe includes a core part and a clad part arranged along an outer circumference of the core part, and has an incident surface having a radius of curvature R through which an optical signal enters. The radius of curvature R and a central half angle ω at an incident point of the optical signal on the incident surface fulfil the following formulae using a radiation angle γ of the optical signal, an effective incident radius Se of the optical signal transmitted in the core part without penetrating into the clad part on the incident surface, a refractive index n(r) of the core part at the incident point, and a refracting angle β at the incident point:

R=Se/sin(ω)

ω=±sin.sup.−1{[K2.sup.2/(K1.sup.2+K2.sup.2)].sup.1/2}

where K1=n(r)×cos(β)−cos(γ/2) and K2=n(r)×sin(β)−sin(γ/2).

This application relates to a method of preparing a composite material for a semiconductor test socket, and a composite material prepared through the method. In one embodiment, the method includes preparing a powder mixture including (i) a metal powder comprising aluminum or aluminum alloy particles and magnesium particles and (ii) a polymer powder. The method may also include sintering the powder mixture to produce the composite material using a spark plasma sintering (SPS) process. This application also relates to a method of manufacturing a semiconductor test socket, the method including forming an insulating portion of the semiconductor test socket with the composite material. This application further relates to a semiconductor test socket produced through the method.

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 semiconductor package test system includes a test pack on which a semiconductor package is loaded, and a semiconductor package testing apparatus. The semiconductor package testing apparatus includes a receiving section that receives the test pack. The receiving section includes a pack receiving slot into which the test pack is inserted. The test pack includes a chuck on which the semiconductor package is fixed, a probe block disposed above the chuck, and a connection terminal. The receiving section includes a receiving terminal that is electrically connected to the connection terminal when the receiving terminal contacts the connection terminal. The probe block includes at least one needle configured to be electrically connected to the semiconductor package disposed on the chuck upon the chuck moving toward the semiconductor package. The receiving section is provided in plural.

To provide an electric component socket in which a pressing surface of a pressing member is prevented from contacting a contact pin when the socket is pressed by the pressing surface in a state where a first electric component is not housed in the socket. A pressing surface of a pressing mechanism contacts a first electric component when the pressing mechanism is moved downward in a state where the first electric component is housed in a plate. On the other hand, when the pressing mechanism is moved downward in a state where the first electric component is not housed in the plate, a push-up member is lifted up with the plate to push up the pressing surface. Therefore, the pressing surface is moved upward to prevent the pressing surface from contacting the contact pin.

Embodiments of the present invention provide testing systems with liquid cooled thermal arrays that can pivot freely in three dimensions allowing surfaces to be brought into even, level, and secure contact, thereby preventing air gaps between surfaces and improving thermal performance. In this way, more DUTs can be tested in parallel within a small test space, overall costs of the test system are reduced, and greater cooling capacity can be provided for testing high-powered devices. Gimbaled mounts are disposed on a bottom surface of individual thermal interface boards (TIBs) of a test system, and/or on top of individual thermal heads of a thermal array (TA) having a common cold plate (or having multiple cold plates).