Abstract: A contact probe capable of being used for an inspection of a semiconductor package in which a recess is formed in a terminal portion includes a plunger including a distal end portion that comes into contact with the terminal portion. The distal end portion includes a protruding portion protruding toward the terminal portion and a shoulder portion having a protruding height toward the terminal portion lower than that of the protruding portion.

Abstract: An upper mechanism including a table provided with a placement surface of an inspection target, a lower mechanism configured to rotatably support the upper mechanism, and a lifting operation unit configured to be supported by the upper mechanism so as to be movable up and down are provided. The lower mechanism includes a rotation drive unit configured to rotate the upper mechanism, and a push-up force output unit configured to lift and lower the lifting operation unit. A transmission member with which a tip of the push-up force output unit can contact or separate is provided at a lower end of the lifting operation unit.

Abstract: A circuit probe includes a shielding probe having a base and a conductive probe ring on the base. A shielding cage is attached to the conductive probe ring and has an interior. The shielding cage is configured to be positioned to contain in the interior of the shielding cage at least one integrated circuit formed on a wafer, and to provide electromagnetic shielding of the at least one integrated circuit during testing of the at least one integrated circuit.

Abstract: A probe pin is proposed. The probe pin includes a first plunger configured to come in contact with a testing target contact point of a testing object and a second plunger configured to come in contact with a testing contact point of a testing circuit, in which the first plunge or the second plunger has a stem extending with a predetermined cross-sectional area and a contact portion extending from the stem such that a cross-sectional area decreases, and having first second tips, which are configured to come in contact with the testing target contact point or the testing contact point, at a front end; and the first and second tips are formed in symmetric shapes at positions that are symmetric with a central axis of the stem therebetween.

Abstract: A probe card is configured to perform a circuit test on a wafer to realize a reduction in size and pitch of probe insertion holes. The probe card includes a first plate, a second plate coupled to a lower portion of the first plate, an upper guide plate provided on an upper surface of the first plate, a lower guide plate provided on a lower surface of the second plate, and a reinforcing plate coupled to at least a surface of each of the upper and lower guide plates. At least one of the upper and lower guide plates is made of an anodic oxide film material, and as viewed from above, the upper and lower guide plates and the reinforcing plate are configured to have smaller areas than the first and second plates, so that upper and lower surfaces of the first and second plates are exposed.

Abstract: Vertical transmission line probes having alternating capacitive and inductive sections are provided. These alternating sections can be designed to provide a desired transmission line impedance (e.g., between 10 and 100 Ohms, preferably 50 Ohms). Probe flexure in operation is mainly in the inductive sections, advantageously reducing flexure stresses on the dielectrics in the capacitive sections.

Abstract: A probe head and a conductive probe thereof are provided. The conductive probe includes a first long lateral surface and an opposite second long lateral surface. The first long lateral surface and the second long lateral surface define a central axis there-between. The conductive probe includes a middle segment, an upper connecting segment and a lower connecting segment respectively extending from the middle segment in two opposite directions, and an upper contacting segment and a lower contacting segment respectively extending from the upper and the lower connecting segments in two opposite directions. The upper connecting segment includes an extension extending from the first long lateral surface in a direction away from the central axis. The upper contacting segment includes a protrusion extending from the first long lateral surface in a direction away from the central axis, and the extension and the protrusion are spaced apart from each other.

Abstract: A testing head comprises at least one guide provided with a plurality of guide holes, and a plurality of contact elements housed in the plurality of guide holes. Suitably, the at least one guide comprises a plurality of conductive layers, each conductive layer: including holes of a corresponding plurality of group of the plurality of guide holes and electrically connecting a corresponding group of contact elements housed in the guide holes of the group, contact elements of a group being adapted to carry a same type of signal. The at least one guide is a multilayer comprising a plurality of non-conductive layers, and the conductive layers are arranged on respective faces of a layer of the plurality of non-conductive layers.

Abstract: A test probe for testing electric characteristics of an object to be tested. The test probe includes: a first contact portion; a second contact portion movable close to or away from the first contact portion; and an elastic deformation portion connecting the first contact portion and the second contact portion and elastically deformed by compression in a probe axial line direction, wherein at least one of the first contact portion and the second contact portion comprises a plurality of split contact portions separated by a first slit formed along a lengthwise direction. According to the present disclosure, the plurality of split contact portions are configured to independently contact the tested contact point of the object to be tested, thereby not only enhancing contact reliability but also securing contact reliability by an alternative split contact portion even though one of the split contact portions is defective or damaged.

Abstract: A test device for testing electric characteristics of an object to be tested. The test device includes: a first support member comprising a plurality of guide holes; a second support member comprising a plurality of terminal holes and arranged to be spaced apart from and in parallel with the first support member; a plurality of main contact probes; and a plurality of sub contact probes arranged to be adjacent to the main contact probes along a lengthwise direction. According to the present disclosure, contact reliability is improved by multi contact with the terminal of the test circuit board (interposer) and/or the object to be tested.

Abstract: A power management module comprises one or more power converter chips that are mounted on a power management package substrate. First and second electrical contacts are disposed on opposing first and second sides of the power management package substrate. The power management module can be mounted on a processor module to supply power to one or more processor chips in the processor module. In one example, the processor chip(s) are mounted on a first side of a processor package substrate and the power management module is mounted on an opposing second side of the processor package substrate. The power management module and the processor module can be centered and aligned with respect to each other or they can be offset laterally from each other. In another embodiment, the processor chip(s) are embedded in the processor package substrate.

Abstract: A power management module comprises one or more power converter chips that are mounted on a power management package substrate. First and second electrical contacts are disposed on opposing first and second sides of the power management package substrate. The power management module can be mounted on a processor module to supply power to one or more processor chips in the processor module. In one example, the processor chip(s) are mounted on a first side of a processor package substrate and the power management module is mounted on an opposing second side of the processor package substrate. The power management module and the processor module can be centered and aligned with respect to each other or they can be offset laterally from each other. In another embodiment, the power management module and the processor chip(s) are mounted on the same side of the processor package substrate.

Abstract: The present invention provides a metal wire rod composed of iridium or an iridium alloy, wherein the number of crystal grains on any cross-section in a longitudinal direction is 2 to 20 per 0.25 mm2, and the Vickers hardness at any part is 200 Hv or more and less than 400 Hv. The iridium wire rod is a material which is produced by a ?-PD method, and has low residual stress and which has a small change in the number of crystal grains and hardness even when heated to a temperature equal to or higher than a recrystallization temperature (1200° C. to 1500° C.). The metal wire rod of the present invention is excellent in oxidative consumption resistance under a high-temperature atmosphere, and mechanical properties.

Abstract: A transverse optical transmission probe having a probe body and a probe tip. The probe use optical fibers to both transmit radiation from an instrument to the probe tip and to return the sample affected radiation to the instrument. The fibers are in parallel and contained in the probe body. The probe tip includes two optical elements that protrude into the sample and are configured to define a sample gap so that incident radiation pass through the sample in a direction transverse to the axis to the probe and eventually reaches the receiving fiber. Each of the optical elements may be formed from a single piece of material or may be a composite formed by adhering two or more pieces of material together. One or more lensed surfaces may be used to cause the end of the transmitting fiber to be imaged on the end of the receiving fiber.

Abstract: A probe connector assembly includes a carrier plate, multiple probes and multiple positioning members. The multiple probes are mounted into multiple probe holes of the carrier plate. Each positioning member is securely mounted into the carrier plate and partially protrudes into corresponding probe holes to contact probe trunks of corresponding probes, such that the probe trunk of each probe is positioned in a corresponding probe hole of the carrier plate by friction resistance generated between the probe trunk and positioning members adjacent to the probe trunk. Thus, the probe connector assembly is advantageous in a simplified structure of the carrier plate and reduced thickness of the carrier plate and probe length.

Abstract: The method for forming a semiconductor probe tip comprises depositing a first copper layer onto exposed electrically conductive areas of a wafer. The first copper layer surrounds a non-conductive polymer structure on the wafer. The non-conductive polymer structure is removed to form a primary cavity in the first copper layer. The wafer and the primary cavity are coated with a polymer layer. Regions of the polymer layer are removed to form a secondary cavity within and alongside the primary cavity. A metal layer is deposited on exposed electrically conductive areas of the wafer and within bounds of the secondary cavity.

Abstract: A probe card, includes, a wiring substrate having an opening portion and including a first connection pad and a second connection pad, the first connection pad being arranged at a periphery of the opening portion, the second connection pad being arranged to be adjacent to the first connection pad, a resin portion formed inside the opening portion of the wiring substrate, a first wire buried in the resin portion and having one end connected to the first connection pad and the other end constituting a first contact terminal protruding from a lower face of the resin portion, and a second wire buried in the resin portion and having one end connected to the second connection pad and the other end constituting a second contact terminal protruding from a lower face of the resin portion.

Abstract: A method for testing a semiconductor device. The method comprises moving a probe in a vertical direction towards an electrical structure on a semiconductor device to position the probe alongside the electrical structure. A tip of the probe is positioned lower than an elevation of an outermost periphery of the electrical structure. The method also includes moving the probe in a lateral direction towards the electrical structure to contact the electrical structure. The probe tip mechanically and electrically engages the electrical structure.

Abstract: A monitoring system for connector pins exposed to conductive/corrosive fluids and/or corrosive environments includes a first sensing portion having a pin monitoring section configured to measure a pin current flow of at least one conductor pin, and transfer a first signal. A second sensing portion produces a second signal indicating by a contactless determination the presence of a fastener providing physical connection between an interface member and a component. A decision logic device receives the first and second signals, compares the pin current flow to a predetermined range of values, and isolates electrical power to the conductor pin when the first signal indicates the pin current flow is outside the predetermined range of values. A sensor body created of a non-ferrous material and connected to the component includes a first insert member having the conductor pin and a second insert member defining a sensor sensing proximal presence of the fastener.

Abstract: An electrical testing apparatus for testing an electrical test sample. The apparatus includes a conductor substrate which is electrically connected via a contact spacing converter to a test head. The conductor substrate is mechanically connected to a first stiffening device and is thereby stiffened. At least one spacer which penetrates the conductor substrate is mechanically connected to the contact spacing converter and is held on the first stiffening device via at least one tilt adjusting arrangement.

Abstract: A variable pressure probe pin device, including: a housing with a channel having a first longitudinal axis; a probe at least partially disposed in the channel and including a plurality of probe pins configured to measure a property of a conductive layer; and a fluid pressure system configured to supply pressurized fluid o the channel to control a position of the probe within the channel. The housing or the probe is displaceable such that the plurality of probe pins contact the conductive layer.

Abstract: A test device including cobra probes and a method of manufacturing is disclosed. The test device includes a conductive upper plate having an upper guide hole and a conductive lower plate having a lower guide hole. The test device also includes a conductive cobra probe disposed between the upper guide hole of the upper plate and the lower guide hole of the lower plate. A dielectric material insulates the cobra probe from the upper plate and the lower plate.

Abstract: An inspection apparatus includes an insulating substrate, a probe pin having a body portion secured to the insulating substrate, a tip portion connected to one end of the body portion and disposed on the back surface side of the insulating substrate, and a connection portion connected to the other end of the body portion and disposed on the front surface side of the insulating substrate, and a heat-radiating terminal in contact with the connection portion, wherein a current is applied through the heat-radiating terminal and the probe pin to an object to measured, and wherein the heat-radiating terminal discharges heat from the probe pin.

Abstract: A probe for inspecting electronic components, and more particularly, to a probe for inspecting electronic components, which connects a target electronic component to an inspection apparatus to inspect defects of the target electronic component. The probe for inspecting electronic components includes: a cylinder body having a cylindrical shape; a piston body reciprocating between an inside and an outside of the cylinder body; a spring surrounding an outer circumference of the cylinder body and the piston body, and forcing a part of the piston body to resiliently move out of the cylinder body when inserted into the cylinder body; a probing unit extending from the cylinder body to be brought into contact with a target electronic component to be inspected as to flow of electric current therethrough; and a contact unit extending from the piston body to be connected to an inspection apparatus for inspecting the target electronic component.

Abstract: A probe module for testing an electronic device comprises at least two contacts, each contact including a first end portion extending in a first direction along a first line, a second end portion extending linearly in a second direction opposite from the first direction and along a second line, and a third curved portion extending between the first end portion and the second end portion. The first line is spaced apart from and in parallel with the second line, and the at least two contacts are spaced apart from each other in a direction perpendicular to the first line and the second line. Methods for making such a probe module are also taught.

Abstract: A wafer probing system includes a probe card assembly having a plurality of individual probe structures configured make contact with a semiconductor wafer mounted on a motor driven wafer chuck, with each probe structure configured with a pressure sensing unit integrated therewith; and a controller configured to drive the probe card assembly with one or more piezoelectric driver units response to feedback from the pressure sensing units of the individual probe structures.

Abstract: The resistive probing tip system has one or more carriers and one or more electrical contact assemblies. Each carrier has opposing surfaces with a plurality of resistors engaging the carrier. Each of the plurality of resistors has opposing electrical contacts that are exposed at respective opposing surfaces of the carrier. Each electrical contact assembly has opposing surfaces with electrical contacts exposed at the opposing surfaces with each electrical contact exposed on one surface coupled to a corresponding electrical contact on the other opposing surface. The carrier(s) and the electrical contact assembly(s) selectively mate to and mate from one another with the electrical contacts exposed at the opposing surfaces the carrier(s) and the electrical contact assembly(s) contacting one another. The carrier(s) and/or the electrical contact assembly(s) may be selectively secured to either of a circuit board or a probe head.

Abstract: Embodiments of the present invention are directed to adjustable test probe tips that are indexable. In one embodiment a mechanism is coupled to a probe tip so that the mechanism may be used to index the probe tip to a plurality of particular positions. A label portion may be provided to communicate to a user that the length of the exposed probe tip is less than a particular length, such as the maximum length an exposed probe tip may be for a particular application.

Abstract: A probe needle for connecting to a circuit board for inspection and to an inspection main board of a testing apparatus includes a conductive shaft having two ends of a connection end and an inspection end for contacting with the circuit board for inspection. An elastic conductive rod is axially connected to the conductive shaft and having two ends of a free end and a fixed end; wherein the free end is connected to the connection end of the conductive shaft and the fixed end abuts the inspection main board. The probe needle has a simplified structure facilitating the manufacturing of parts and assembly thereof.

Abstract: A probe structure is disclosed which includes a metal needle, a soft insulative tube and a metal layer. The metal needle has a first end-portion and a second end-portion opposite to each other. The first end-portion has a tip. The soft insulative tube has a through hole in which the metal needle is partially inserted. The tip of the metal needle protrudes from the through hole. The metal layer is coated on the outer surface of the soft insulative tube and is electrically isolated from the metal needle; the thickness of the metal layer has a thickness no larger than 10 micrometers. Therefore, good resilience and signal integrity could coexist in the probe structure. A probe card including several above-mentioned probe structures and a method for manufacturing the above-mentioned probe structure are also disclosed.

Abstract: A semiconductor device includes a plurality of sensor pads configured to receive a probe signal from a testing apparatus, and a plurality of normal pads configured to receive a driving signal to drive the semiconductor device. In the plurality of sensor pads and the plurality of normal pads, a length in a direction corresponding to one of progress directions of a plurality of needles of the testing apparatus is longer than a length in another progress direction of the plurality of needles.

Abstract: Structures having a plurality of discrete insulated elongated electrical conductors projecting from a support surface which are useful as probes for testing of electrical interconnections to electronic devices, such as integrated circuit devices and other electronic components and particularly for testing of integrated circuit devices with rigid interconnection pads and multi-chip module packages with high density interconnection pads and the apparatus for use thereof and to methods of fabrication thereof. Coaxial probe structures are fabricated by the methods described providing a high density coaxial probe.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. Some embodiments are directed to various designs of cantilever-like probe structures while other embodiments are directed to methods for fabricating probe structures. In some embodiments, methods are used to form probe structures from a plurality of planar multi-material layers wherein each probe structure includes a contact tip and a compliant body wherein a portion of the complaint body is formed, then the contact tip is formed and then finally the rest of the compliant body is formed, wherein the compliant body provides for elastic compression of the probe in a plane of primary motion during use and wherein during formation of the layers a stacking direction of the plurality of layers is perpendicular to the plane of primary motion.

Abstract: An assembly includes a lower guide plate having a first plurality of through-holes therein, and an upper guide plate over the lower guide plate. The upper guide plate includes a second plurality of through-holes therein. The assembly further includes a plurality of probe pins. Each of the probe pins is inserted through one of the first plurality of through-holes and one of the second plurality of through-holes. The assembly further includes a plurality of probe pin stoppers, each attached to one of the probe pins, wherein the plurality of probe pin stoppers has lateral sizes greater than lateral sizes of the second plurality of through-holes. The plurality of probe pin stoppers is located over the upper guide plate.

Abstract: An exemplary embodiment of the present invention provides a vertical micro contact probe that includes a column formed by longitudinally continuously stacking a plurality of basic units and a front end formed at the front end of the column and contacting an electrode pad of a semiconductor chip. The basic unit includes a probe body alternately bending to the left and right and protrusions protruding from the probe body at the left and right sides from the center of the width direction, and contacting the adjacent probe body to support the probe body under compression.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. Some embodiments are directed to various designs of cantilever-like probe structures while other embodiments are directed to methods for fabricating probe structures. In some embodiments, methods are used to form probe structures from a plurality of planar multi-material layers wherein each probe structure includes a contact tip, a compliant body, and a bonding material that can be used in bonding the probe to a substrate and wherein the compliant body provides for elastic compression of the probe in a plane of primary motion during use and wherein during formation of the layers a stacking direction of the plurality of layers is perpendicular to the plane of primary motion.

Abstract: A testing jig of a pogo pin connector for testing a connection between at least one pogo pin and an electrical plug is disclosed. The testing jig includes a first support element, a second support element, and a platform. The first support element has a first groove and at least one opening defined therein. The second support element has a second groove corresponding to the first groove for receiving the electrical plug. The platform is disposed below the first support element, and at least one receiving hole is defined in the platform. The at least one pogo pin is disposed in the at least one receiving hole and exposed in the first groove through the at least one opening. The pogo pin is configured in various tilt angles through the platform with the opening for solving high cost of various mold developments.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. Some embodiments are directed to various designs of cantilever-like probe structures while other embodiments are directed to methods for fabricating probe structures. In some embodiments, methods of forming probe structures include formation of a plurality of planar multi-material electrodeposited layers wherein each probe structure includes a contact tip and a compliant body, wherein the compliant body is formed from at least one material that is different from the contact tip material and wherein the compliant body provides for elastic compression of the probe in a plane of primary motion during use and wherein during formation of the layers a stacking direction of the plurality of layers is perpendicular to the plane of primary motion.

Abstract: A mechanism is described for facilitating a dynamic electro-mechanical interconnect capable of being employed in a test system according to one embodiment. A method of embodiments of the invention may include separating, via a cavity, a first conductor of an interconnect from a second conductor of the interconnect, and isolating, via the cavity serving as a buffer, a first electrical path provided through the first conductor from a second electrical path provided through the second conductor.

Abstract: A method for manufacturing a probed for an electrical test includes producing by a deposition technique a deposit including a probe main body portion made of a nickel-boron alloy and a probe tip portion projecting downward from the probe main body portion and made of a different conductive material from the probe main body portion. The method further includes annealing the deposit. The average grain diameter of the nickel-boron alloy is between 97 ? and 170 ?. The contained amount of boron is from 0.02 wt % to 0.20 wt %.

Abstract: Disclosed herein is an electrical component including a substrate comprising an electroconductive filler in a first polymeric binder, and a coating layer adhered to at least a portion of the substrate surface, the coating layer comprising a nanostructured electroconductive particulate dispersed in a polymeric binder, such as an epoxy resin. A method of making the component also is disclosed, comprising obtaining a substrate containing an electroconductive filler in a polymeric binder, dispersing a nanostructured electroconductive particulate filler in a liquid that includes a solvent and/or a reactive diluent to form a dispersion, mixing the dispersion with a liquid resin to form a coating mixture, applying the coating mixture to the substrate, and crosslinking the applied coating mixture to form the coated substrate.

Abstract: The probe pin includes a plunger formed of a sheet metal, and a coil spring unit formed of a metal wire and configured to hold the plunger thereon. In a developed state, the plunger includes first and second portions each of which has an upper contact strip, a wide portion, and a lower contact strip, and which are connected to each other via the wide portions formed in the first and second portions. The plunger is formed in a united manner by folding together the first and second portions along a boundary of the wide portions formed therein to thereby bring at least the wide portions into tight contact with each other.

Abstract: A semiconductor package and testing method is disclosed. The package includes a substrate having top and bottom surfaces, a semiconductor chip mounted in a centrally located semiconductor chip mounting area of the substrate, and a plurality of test pads disposed on top and bottom surfaces of the substrate and comprising a first group of test pads configured on the top and bottom surfaces of the substrate and having a first height above the respective top and bottom surface of the substrate, and a second group of test pads disposed on the lower surface of the substrate and having a second height greater than the first, wherein each one of the second group of test pads includes a solder ball attached thereto.

Abstract: The present idea refers to a needle head, its use in a probe arrangement, and a method for electrically contacting multiple electronic components. The needle head comprises a body with a lower surface, needle electrodes emerging from the lower surface, and multiple outlets arranged in the lower surface. A channel is arranged between an inlet in the body and the outlets for conveying a medium from the inlet to the outlets. By this means, electronic components arranged in close distance under the lower surface of the needle head are directly exposed to the medium which provides a test environment during a test of the electronic components.

Abstract: A deflection measurement probe includes a body portion having a cavity defined by the body portion, a first positional measurement sensor disposed in the cavity of the body portion, the first positional measurement sensor including a sensor tip extending from the body portion operative to contact a measurement surface, and a second positional measurement sensor disposed in the cavity of the body portion, the first positional measurement sensor including a sensor tip extending from the body portion operative to contact a measurement surface.

Abstract: A test probe for testing an object electrically includes a main body, a first probe pin mounted to and protruding out of the main body, and at least one second probe pin coupled to the main body. The at least one second probe pin is changeable from a first state of being folded into the main body to a second state of being unfolded to protrude out of the main body. When the at least one second probe pin is in the first state, the first probe pin is used to contact the object, and when the at least one second probe pin is in the second state, the at least one second probe pin takes the place of the first probe pin in making electrical connection with the object.

Abstract: An I/O pin is connected to a DUT via a transmission line. A driver generates a test signal to be supplied to the DUT. A driver-side switch and an output resistor are arranged in series between the driver and the I/O pin. A comparator is arranged such that the input terminal thereof is connected to the I/O pin, and configured to judge the level of a signal output from the DUT. A short-circuit switch is arranged between the I/O pin and the ground terminal.

Abstract: The present invention is a rhodium alloy suitable for wire for a probe pin, the rhodium alloy comprising 30 to 150 ppm of Fe, 80 to 350 ppm of Ir and 100 to 300 ppm of Pt as additive elements, and the balance being Rh. A probe pin composed of the material maintains processability of rhodium, has stable contact resistance even at a low contact pressure, and has excellent strength and antifouling properties, and therefore, can be used in a stable manner for a long period.

Abstract: There is provided a probe block comprising a probe including first contact portions, second contact portions, and beams connecting the first contact portion to the second contact portion and a guide where the probe is inserted and supported, wherein the probe block is installed in a probe card for inspecting a semiconductor chip.

Abstract: A semiconductor package test apparatus having a test head and a test handler is provided. The semiconductor package test apparatus may include an insert in which a plurality of semiconductor packages are stacked and received in an offset fashion. Further, the semiconductor package test apparatus may include a plurality of sockets located adjacent to the insert and each of the inserts may have a plurality of socket pins. The sockets have different surface levels and are aligned with the semiconductor packages.