A sensor test apparatus having excellent versatility is provided. The sensor test apparatus includes a first application unit 40 including a first application device including a socket to which the sensor is electrically connected, and a pressure chamber 43 which applies pressure to the sensor, a test unit which tests the sensor 90 via the socket, a conveying robot which conveys the sensor into and out of the first application unit 40, and an apparatus main body which houses the first application unit 40, the test unit 35 and the conveying robot, and the apparatus main body has an opening which allows the first application unit 40 to be inserted into the apparatus main body and removed from the apparatus main body to an outside.

A diagnostic test instrument for testing power system equipment may include a chassis having a number of bays capable of receiving test circuitry modules, which may be field inserted by a user desiring to perform a particular test. The instrument may include controller circuitry that may sense in each of the bays whether a respective test circuitry module is inserted therein, and then interrogate respective test circuitry modules in each respective bay to identify a type of the respective test circuitry module. Available testing capabilities may be identified according to the type of each of the respective test circuitry modules identified in respective bays. The controller circuitry may output configuration instructions to test circuitry modules, and respective test ports included in each of the respective test circuitry modules may be selectively illuminated as a configuration instruction to visually identify an assigned functionality of the respective test ports.

An automated test equipment (ATE) includes a test interface board assembly. The test interface board includes a socket configured to provide electrical couplings from the test interface board to a device under test (DUT). The socket is further configured to accept an active thermal interposer (ATI) device while the DUT is disposed in the socket. The socket includes a plurality of spring-loaded roller retention devices configured to retain one or more devices in the socket. The ATE further includes a Z-axis interface plate configured to open the plurality of spring-loaded roller retention devices to enable insertion of the DUT into the socket and an ATI placement plate configured to open the plurality of spring-loaded roller retention devices to enable insertion of the ATI device into the socket.

A chip test carrier for carrying chips includes a circuit board, a positioning seat, a chip frame, and a pressing cover unit. The positioning seat includes upper and lower plates cooperating to clamp the circuit board therebetween. The upper plate includes a chip-mounting portion and an engaging slot. The chip frame is disposed on the chip-mounting portion, and is formed with frame slots for accommodating the chips, respectively. The cover unit includes a cover body connected pivotably to the positioning seat, an engaging member pivotably connected to the cover body and detachably engages the engaging slot, and pressing blocks connected to the cover body and pressing respectively against the chips.

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 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.

An embodiment of the present invention provides a conductive particle used for a testing socket electrically connecting a lead of a device to be tested and a pad of a test board by being arranged between the device to be tested and the test board, wherein the conductive particle comprises a plurality of protrusions formed at equal intervals along a circumference.

Provided is a handler apparatus that conveys a device under test to a test socket, including: a socket for adjustment which, prior to fitting of a device holder holding the device under test to the test socket, fits the device holder; a socket-for-adjustment position detecting section that detects a relative position of the device under test with respect to the socket for adjustment, in a state in which the device holder fits the socket for adjustment; an actuator that adjusts a position of the device under test on the device holder, based on the detected relative position of the device under test; and a conveyer that conveys the device holder, in which a position of the device under test has been adjusted, to fit the test socket.

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 socket includes: a contact probe; and an insulating support body supporting the contact probe. The contact probe includes: a first plunger to be connected with an object to be inspected; a second plunger to be connected with an inspecting board; and a spring configured to urge the first plunger and the second plunger in a direction apart from each other. In a state where a tip end of the first plunger is released, a projecting amount of the second plunger from the insulating support body is zero with a natural length of the spring.