The present disclosure includes a die test pressing-down apparatus and a formation method. The die test pressing-down apparatus includes a support frame capable of moving along a vertical direction; and a pressing-down block installed on the support frame. A part to-be-pressed is disposed directly below the pressing-down block. The pressing-down block is connected to the support frame through an installation plate; a strip-shaped through hole is formed at an upper surface of the support frame; a first protruding strip is at each lower portion of two opposite inner walls of the strip-shaped through hole; a corresponding second protruding strip is at each upper portion of two opposite side surfaces of the installation plate; and a side of a strip-shaped block is fixedly connected to the upper surface of the support frame, and another side of the strip-shaped block is connected to the second protruding strip through at least two springs.

The present disclosure includes an adaptive die test socket and a formation method. The die test socket includes an upper test socket and a lower test socket disposed directly below the upper test socket. The upper test socket is connected to a support frame; a strip-shaped through hole is formed on an upper surface of the support frame; a first protruding strip is at each of lower portions of two opposite inner walls of the strip-shaped through hole; a corresponding second protruding strip is at each of upper portions of two opposite side surfaces of the installation plate; and a side of a strip-shaped block is fixedly connected to the upper surface of the support frame, and another side of the strip-shaped block extends to directly above the second protruding strip and is connected to the second protruding strip through at least two springs.

The present disclosure includes an adaptive die test socket and a formation method. The die test socket includes an upper test socket and a lower test socket disposed directly below the upper test socket. The upper test socket is connected to a support frame; a strip-shaped through hole is formed on an upper surface of the support frame; a first protruding strip is at each of lower portions of two opposite inner walls of the strip-shaped through hole; a corresponding second protruding strip is at each of upper portions of two opposite side surfaces of the installation plate; and a side of a strip-shaped block is fixedly connected to the upper surface of the support frame, and another side of the strip-shaped block extends to directly above the second protruding strip and is connected to the second protruding strip through at least two springs.

The terminals of a device under test (DUT) are temporarily electrically connected to corresponding contact pads on a load board by a series of electrically conductive pin pairs. The pin pairs are held in place by an interposer membrane with a top facing the device under test, a bottom facing the load board, and a vertically resilient, non-conductive member between the top and bottom contact plates. Each pin pair includes a top and bottom pin, which extend beyond the top and bottom contact plates, respectively, toward the device under test and the load board, respectively. The bottom pins has a lower contact surface which includes an arcuate portion or ridge which increases contact pressure and ablates oxides by the rocking action of ridge when the DUT in inserted.

The terminals of a device under test (DUT) are temporarily electrically connected to corresponding contact pads on a load board by a series of electrically conductive pin pairs. The pin pairs are held in place by an interposer membrane with a top facing the device under test, a bottom facing the load board, and a vertically resilient, non-conductive member between the top and bottom contact plates. Each pin pair includes a top and bottom pin, which extend beyond the top and bottom contact plates, respectively, toward the device under test and the load board, respectively. The bottom pins has a lower contact surface which includes an arcuate portion or ridge which increases contact pressure and ablates oxides by the rocking action of ridge when the DUT in inserted.

Embodiments related to the generation of magnetic bias fields for magnetic sensing are described and depicted. In one embodiment, a sensor includes at least one magnetosensitive element, and a magnetic body with an opening, the magnetic body comprising magnetic material, the magnetic body having inclined surface sections shaped by the opening, wherein the sensor is arranged within the opening such that the magnetosensitive element is in lateral directions bounded by the inclined surface sections.

A probe device includes a spring probe and a probe seat. The spring probe includes a needle and a spring sleeve sleeved onto the needle and provided with at least one spring section and at least one non-spring section. The probe seat includes a plurality of dies stacked together and at least one guiding hole through which the spring probe is inserted. An upper edge and a lower edge of the guiding hole of the probe seat are arranged corresponding in position to the non-spring section of the spring sleeve. As a result, the spring probe is prevented from getting jammed due to the contact of the spring section of the spring sleeve with the upper and lower edges of the guiding hole.

A probe device includes a spring probe and a probe seat. The spring probe includes a needle and a spring sleeve sleeved onto the needle and provided with at least one spring section and at least one non-spring section. The probe seat includes a plurality of dies stacked together and at least one guiding hole through which the spring probe is inserted. An upper edge and a lower edge of the guiding hole of the probe seat are arranged corresponding in position to the non-spring section of the spring sleeve. As a result, the spring probe is prevented from getting jammed due to the contact of the spring section of the spring sleeve with the upper and lower edges of the guiding hole.

Nanospike contactors suitable for semiconductor device test, and associated systems and methods are disclosed. A representative apparatus includes a package having a wafer side positioned to face toward a device under test and an inquiry side facing away from the wafer side. A plurality of wafer side sites are carried at the wafer side of the package. The nanospikes can be attached to nanospike sites on a wafer side of the package. Because of their small size, multiple nanospikes make contact with a single pad/solderball on the semiconductor device. In some embodiments, after detecting that the device under test passes the test, the device under the test can be packaged to create a known good die in a package.

A probe insertion auxiliary and a method of probe insertion are provided. A light source illuminates holes on a lower die to make the position of the holes clear for an operator. The probe insertion auxiliary includes a bottom and a clamp pair disposed on the bottom. The clamp pair has two clamp parts. The two clamp parts define a slit for disposing a probe chassis. Furthermore, the two clamp parts and the bottom form a space. A light source is disposed inside the space for illuminating the holes.