A probe card device and a self-aligned probe are provided. The self-aligned probe includes a fixing end portion configured to be abutted against a space transformer, a testing end portion configured to detachably abut against a device under test (DUT), a first connection portion connected to the fixing end portion, a second connection portion connected to the testing end portion, and an arced portion that connects the first connection portion and the second connection portion. The fixing end portion and the testing end portion jointly define a reference line passing there-through. The first connection portion has an aligned protrusion, and a maximum distance between the arced portion and the reference line is greater than 75 μm and is less than 150 μm.

A probe card device and a transmission structure are provided. The transmission structure includes a supporting layer, a plurality of metal conductors spaced apart from each other and slantingly inserted into the supporting layer, and an insulating resilient layer formed on the supporting layer. Each of the metal conductors includes a positioning segment held in the supporting layer, a connecting segment and an embedded segment respectively extending from two ends of the positioning segment, and an exposed segment extending from the embedded segment. Each of the embedded segments is embedded and fixed in the insulating resilient layer, and each of the exposed segments protrudes from the insulating resilient layer. When any one of the exposed segments is pressed by an external force, the insulating resilient layer is configured to absorb the external force through the corresponding embedded segment so as to have a deformation providing a stroke distance.

The present disclosure provides a probe and a probe card device. The probe card device includes a first plate and a plurality of probes. The probes are arranged through the first plate, and include a first probe and a second probe. The first probe has a first body and an end portion of the first body. The end portion of the first body has a first recess and a first protrusion. The second probe has a second body and an end portion of the second body. The end portion of the second body has a second recess and a second protrusion. The second protrusion extends into the first recess.

A probe card device including a probe structure is provided. Probes respectively pass through multiple through holes on at least two guide plates that are stacked and separated from each other, and each of the probes includes a main body, a contacting portion, a head portion, and a neck portion. The contacting portion is exposed under a lowermost guide plate. The head portion is exposed above an uppermost guide plate. The neck portion is connected between the main body and the head portion, and a part of the neck portion protrudes opposite thereof to form a protrusion portion. The protrusion portion and the main body form an included angle, the protrusion portion abuts against an upper surface of the uppermost guide plate, and a spacing between any two of the probes that are adjacent to each other is less than twice the thickness of the protrusion portion.

Probes that define retroreflectors, probe systems that include the probes, and methods of utilizing the probes. The probes include the retroreflector, which is defined by a retroreflector body. The retroreflector body includes a first side, an opposed second side, a tapered region that extends from the first side, and a light-receiving region that is defined on the second side. The probes also include a probe tip, which is configured to provide a test signal to a device under test (DUT) and/or to receive a resultant signal from the DUT. The retroreflector is configured to receive light, via the light-receiving region, at a light angle of incidence. The retroreflector also is configured to emit at least an emitted fraction of the light, from the retroreflector body and via the light-receiving region, at a light angle of emission that is at least substantially equal to the light angle of incidence.

A probe head structure is provided. The probe head structure includes a flexible substrate having a top surface and a bottom surface. The probe head structure includes a first probe pillar passing through the flexible substrate. The first probe pillar has a first protruding portion protruding from the bottom surface. The probe head structure includes a redistribution structure on the top surface of the flexible substrate and the first probe pillar. The redistribution structure is in direct contact with the flexible substrate and the first probe pillar. The redistribution structure includes a dielectric structure and a wiring structure in the dielectric structure. The wiring structure is electrically connected to the first probe pillar. The probe head structure includes a wiring substrate over the redistribution structure. The probe head structure includes a first conductive bump connected between the wiring substrate and the redistribution structure.

A probe for characteristic inspection of a connector includes a plunger, a coaxial cable, a flange, and a housing having an end portion on one side including an increased diameter portion. A recessed portion which receives the increased diameter portion is in an upper surface of the flange. The increased diameter portion has side walls in contact with or facing respective inner side surfaces of the flange partly, with the inner side surfaces forming the recessed portion, and a bottom wall in contact with an upper recessed surface of the flange that forms the recessed portion. The increased diameter portion has connection surfaces connecting the bottom and side walls and inclined inward from one of the side walls toward the bottom wall. Alternatively, the inner side surfaces each have a first surface inclined downward, and a vertical surface extending downward from the first surface to the upper recessed surface.

A test probe assembly includes: a conductive pipe; a probe inserted in the pipe without contacts and elastically retractable along a lengthwise direction; and an insulation probe supporting member configured to support the probe between an inner wall of the pipe and an outer surface of the probe. The test probe assembly of the present disclosure is improved in noise shield performance and convenient in repairing the probe since the probe is mounted to a probe socket as supported in a metal pipe without contacts.

An inspection jig includes a rod-shaped probe, a first support portion that supports one end portion side of the probe, a second support portion that supports the other end portion side of the probe, and a separation holding member that holds the first support portion and the second support portion to be separated from each other. The first support portion includes a support plate in which a through hole through which the probe is inserted is formed. A reinforcing plate having bending strength stronger than that of the support plate is disposed on a surface of the support plate facing the second support portion.

Pin probes and pin probe arrays are provided that allow electric contact to be made with selected electronic circuit components. Some embodiments include one or more compliant pin elements located within a sheath. Some embodiments include pin probes that include locking or latching elements that may be used to fix pin portions of probes into sheaths. Some embodiments provide for fabrication of probes using multi-layer electrochemical fabrication methods.