The present disclosure relates to the field of display technology, in particular to a test fixture, comprising a pressing connection mechanism (1), an eccentric mechanism (2), and a working carrier (3), the pressing connection mechanism (1) and the working carrier (3) being arranged correspondingly, and the rotation of the eccentric mechanism (2) driving the pressing connection mechanism (1) to move up and down in a Y direction so as to conduct a signal pressing connection test for a tested product on the working carrier (3). The test fixture has a simple structure and steady properties, easy to be operated and maintained conveniently.

The present invention discloses a test probe, a test probe component, and a test platform. The test probe comprises a probe body, wherein one end of the probe body is of a hollow design, thereby cooperating with a gold finger through insertion. According to the present invention, one end of the probe body is of a hollow design, thereby cooperating with the gold finger through insertion, thus solving the current technical problems of the assembling of the probe being relatively difficult, the requirements for processing of the through-hole being relative high, and the powering on being unstable.

Embodiments of a method for forming a device using test structures are presented. The method includes providing a wafer with a device layer. The device layer includes a main device region and a perimeter region. The device layer is patterned with active and test patterns. Test patterns include dummy patterns disposed in a test device area. The wafer is processed to form at least one test device disposed in the perimeter region and one or more active devices disposed in the main device region. The test device determines a design window of the one or more active devices. Additional processing is performed to complete forming the device.

A probe apparatus has probe wires with a contact pattern on one side. The contact pattern is for contacting a respective contact pattern on another test equipment or component, such as a circuit board. The probe wires have tips that probe a device desired for testing. Signals are transmitted through the probe wires from the probe card, for example, through a circuit board to other diagnostic equipment. The contact of the probe card with the circuit board allows signals to be transferred through the probe wires to the other diagnostic equipment. On another side of the probe card is a connector structure. The connector structure includes a retainer that can allow the probe card to be replaced from a test system, such as allowing it to be connected and disconnected from a holder.

A backing apparatus for use in a semiconductor automatic test equipment including: a probe card holder configured to rigidly affix one or more first portions of a flexible probe card to the probe card holder, wherein a respective back side of each of the one or more first portions is adjacent to the probe card holder when the one or more portions are rigidly affixed to the probe card holder; linear actuators; and a rigid backing plate configured to rigidly affix a second portion of the flexible probe card to the rigid backing plate, wherein one side of the rigid backing plate is adjacent to a back side of the second portion when the second portion is rigidly affixed to the rigid backing plate, wherein each linear actuator is configured to provide backing of another side of the rigid backing plate against the probe card holder.

A wafer inspection device 10 is provided with a chuck top 20 on which a wafer W having semiconductor devices formed thereon is placed, a probe card 18 having multiple contact probes 28 protruding toward the wafer W, a pogo frame 23 for holding the probe card 18, a cylindrical internal bellows 26 configured to suspend from the pogo frame 23 to surround the contact probes 28, and a cylindrical external bellows 27 configured to suspend from the pogo frame 23 to surround the internal bellows 26. When the chuck top 20 approaches the probe card 18 and the contact probes 28 are brought into contact with the devices, the internal bellows 26 and the external bellows 27 come in contact with the chuck top 20, a sealing space P is formed between the internal bellows 26 and the external bellows 27, and the sealing space P is compressed.

A method of operating a semiconductor test device includes transferring a first device under test (DUT) from a load tray to a first load shuttle. The first DUT is transferred from the first load shuttle to a first test board and a second DUT is transferred from the load tray to a second load shuttle.

A testing device for wafer level testing of IC circuits is disclosed. An upper and lower pin (22, 62) are configured to slide relatively to each other and are held in electrically biased contact by an elastomer (80). The elastomer is precompressed from its natural rest state between a top (22) plate and a bottom (70). Pre compression improves the resilient response of the pins. The pin crowns (40) are maintained relatively coplanar by the engagement of at least one flange (44a-b) against an up-stop surface 90 of plate 20, thereby insuring coplanarity of the crowns. The pin guide (12) is maintained in alignment with the retainer 14 by establishing a registration corner (506) and driving the guide into the corner by elastomers in at least one diagonally opposite corner.

A testing device includes a base body, a holder, an electrically conductive plate, plural testing probes and plural insulation structures. The testing device of the present invention uses the electrically conductive plate to replace the plastic plate of the conventional testing device. Consequently, the electrostatic discharge effect is avoided. Moreover, the insulation structure is arranged between the testing probe and the electrically conductive plate to separate the testing probe from the electrically conductive plate so as to avoid the electric leakage problem. Consequently, the testing device of the present invention is capable of avoiding the electrostatic discharge effect without causing damage of the under-test object and reducing the measurement accuracy.

In accordance with some embodiments, a high speed connection may be implemented using pogo-pins. The use of pogo-pins may be advantageous because accurate alignment is not required, connection force is generally lower than with other connections and appearance is often highly advantageous. Through the use of a moveable metal shield, an advantageous high speed connection for high speed signaling may be implemented between the two devices.