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 conductive probe may include a probe body for communicating with a circuit tester or a jumper. The probe body may be formed of metal and may have a free end. A probe tip may be mounted to the end of the probe body. The probe tip may be formed of thorium-tungsten. The probe tip may be configured for contacting a circuit node.

Apparatuses and methods of distinguishing between a finger and stylus proximate to a touch surface are described. One apparatus includes a first circuit to obtain capacitance measurements of sense elements when a conductive object is proximate to a touch surface. The apparatus also includes a second circuit coupled to the first circuit. The second circuit is operable to detect whether the conductive object activates the first sense element, second sense element, or both, in view of the capacitance measurements. To distinguish between a stylus and a finger as the conductive object, the second circuit determines the conductive object as being the stylus when the second sense element is activated and the first sense element is not activated and determines the conductive object as being the finger when the first sense element and the second sense element are activated.

A probe card structure is provided. The probe card structure includes a circuit board, an adapter board, and a probe head assembly. The adapter board is disposed on one side of the circuit board, a plurality of electrically conductive pillars are formed on one surface of the adapter board that faces the circuit board. A solder ball is disposed on one end of each of the plurality of electrically conductive pillars facing the circuit board, and the adapter board is coupled to the circuit board through the solder balls of the plurality of electrically conductive pillars. The probe head assembly including a plurality of probes, the probe head assembly is coupled to the adapter board, and the plurality of probes are electrically connected to the adapter board.

Disclosed is a test socket. The test socket includes a first block comprising a first base member of a conductive material and a first insulating member of an insulating material, a second block comprising a second base member of a conductive material and a second insulating member of an insulating material, a gap member of an insulating material, interposed between the first block and the second block, a first probe supported being in contact with the first base member and being not in contact with the second base member, a second probe supported being not in contact with the first base member and being in contact with the second base member, and electronic parts provided in the gap member and placed on a conductive path by which the first base member and the second base member are electrically connected.

In one aspect, a method includes forming a coil in a coil layer, performing planarization on the coil layer, and depositing a magnetoresistance (MR) element on the planarized coil layer. No dielectric material is between the planarized coil layer and the MR element. In another aspect, a magnetic field sensor includes a substrate, a planarized coil layer comprising a coil on the substrate, a magnetoresistance (MR) element in contact with the planarized coil layer, and a capping layer deposited over the MR element and the planarized coil layer. No dielectric material is between the planarized coil layer and the MR element.

In one aspect, a method includes forming a coil in a coil layer, performing planarization on the coil layer, and depositing a magnetoresistance (MR) element on the planarized coil layer. No dielectric material is between the planarized coil layer and the MR element. In another aspect, a magnetic field sensor includes a substrate, a planarized coil layer comprising a coil on the substrate, a magnetoresistance (MR) element in contact with the planarized coil layer, and a capping layer deposited over the MR element and the planarized coil layer. No dielectric material is between the planarized coil layer and the MR element.

The present invention relates to a probe member for a pogo pin, a method of manufacturing the probe member, and a pogo pin including the probe member. An embodiment of the present invention provides a probe member including a first body portion and a second body portion that are stacked in a height direction based on the other end of a contact portion, wherein the probe member is used in a test socket in a state in which at least a portion of the probe member is inserted in a pipe having an internal space.

A plunger comprising: a tip contactor formed by embedding a first conductive material in a recess part provided in a base; a columnar part formed by embedding a second conductive material in a first opening provided in a first resist film formed over the base, the first opening being located above the recess part; and a receiving part formed by embedding a third conductive material in a second opening provided in a second resist film formed over the first resist film, the second opening being located above the first opening.

A plunger comprising: a tip contactor formed by embedding a first conductive material in a recess part provided in a base; a columnar part formed by embedding a second conductive material in a first opening provided in a first resist film formed over the base, the first opening being located above the recess part; and a receiving part formed by embedding a third conductive material in a second opening provided in a second resist film formed over the first resist film, the second opening being located above the first opening.