Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Multi-layer microscale or mesoscale structures are fabricated with adhered layers (e.g. layers that are bonded together upon deposition of successive layers to previous layers) and are then subjected to a heat treatment operation that enhances the interlayer adhesion significantly. The heat treatment operation is believed to result in diffusion of material across the layer boundaries and associated enhancement in adhesion (i.e. diffusion bonding). Interlayer adhesion and maybe intra-layer cohesion may be enhanced by heat treating in the presence of a reducing atmosphere that may help remove weaker oxides from surfaces or even from internal portions of layers.

Abstract: Techniques for displaying virtual objects on devices in differential situations are provided. Augmented reality authoring ensures that users have a consistent experience with virtual objects, including augmented reality images, by delivering the same versions of the virtual objects to devices that are close in terms, for instance, of at least distance and/or time. Devices that are not sufficiently close may receive different versions of the virtual object, thus ensuring that the users of devices that are sufficiently near each other do not experience different versions of the virtual object.

Abstract: Embodiments of invention are directed to the formation of microprobes (i.e. compliant electrical or electronic contact elements) on a temporary substrate, dicing individual probe arrays, and then transferring the arrays to space transformers or other permanent substrates. Some embodiments of the invention transfer probes to permanent substrates prior to separating the probes from a temporary substrate on which the probes were formed while other embodiments do the opposite. Some embodiments, remove sacrificial material prior to transfer while other embodiments remove sacrificial material after transfer. Some embodiments are directed to the bonding of first and second electric components together using one or more solder bumps with enhanced aspect ratios (i.e. height to width ratios) obtained as a result of surrounding the bumps at least in part with rings of a retention material. The retention material may act be a solder mask material.

Abstract: A directional conductivity nanocomposite material, apparatuses and processes for making such material are generally described. A directional conductivity nanocomposite material may comprise a supporting material such as ceramic or polymer, with directionally conductive nanorod structures running through the supporting material. The material may be made by orienting nanorods in an electrophoretic gel using an electrical or magnetic field to align the nanorods, removing the gel, reinforcing the nanorods, and flowing in supporting material.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Embodiments of the present invention are directed to the formation of microprobe tips elements having a variety of configurations. In some embodiments tips are formed from the same building material as the probes themselves, while in other embodiments the tips may be formed from a different material and/or may include a coating material. In some embodiments, the tips are formed before the main portions of the probes and the tips are formed in proximity to or in contact with a temporary substrate.

Abstract: Multilayer probe structures for testing semiconductor die are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments the structures may include generally helical shaped configurations, helical shape configurations with narrowing radius as the probe extends outward from a substrate, bellows-like configurations, and the like. In some embodiments arrays of multiple probes are provided.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Multilayer probe structures for testing or otherwise making electrical contact with semiconductor die or other electronic components are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments the structures may include configurations intended to enhance functionality, buildability, or both.

Abstract: Embodiments disclosed herein are directed to compliant probe structures for making temporary or permanent contact with electronic circuits and the like. In particular, embodiments are directed to various designs of cantilever-like probe structures. Some embodiments are directed to methods for fabricating such cantilever structures. In some embodiments, for example, cantilever probes have extended base structures, slide in mounting structures, multi-beam configurations, offset bonding locations to allow closer positioning of adjacent probes, compliant elements with tensional configurations, improved over travel, improved compliance, improved scrubbing capability, and/or the like.

Abstract: Multilayer test probe structures are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments each probe structure may include a plurality of contact arms or contact tips that are used for contacting a specific pad or plurality of pads wherein the arms and/or tips are configured in such away so as to provide a scrubbing motion (e.g. a motion perpendicular to a primary relative movement motion between a probe carrier and the IC) as the probe element or array is made to contact an IC, or the like, and particularly when the motion between the probe or probes and the IC occurs primarily in a direction that is perpendicular to a plane of a surface of the IC. In some embodiments arrays of multiple probes are provided and even formed in desired relative position simultaneously.

Abstract: Multilayer test probe structures are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments each probe structure may include a plurality of contact arms or contact tips that are used for contacting a specific pad or plurality of pads wherein the arms and/or tips are configured in such away so as to provide a scrubbing motion (e.g. a motion perpendicular to a primary relative movement motion between a probe carrier and the IC) as the probe element or array is made to contact an IC, or the like, and particularly when the motion between the probe or probes and the IC occurs primarily in a direction that is perpendicular to a plane of a surface of the IC. In some embodiments arrays of multiple probes are provided and even formed in desired relative position simultaneously.

Abstract: Multi-layer microscale or mesoscale structures are fabricated with adhered layers (e.g. layers that are bonded together upon deposition of successive layers to previous layers) and are then subjected to a heat treatment operation that enhances the interlayer adhesion significantly. The heat treatment operation is believed to result in diffusion of material across the layer boundaries and associated enhancement in adhesion (i.e. diffusion bonding). Interlayer adhesion and maybe intra-layer cohesion may be enhanced by heat treating in the presence of a reducing atmosphere that may help remove weaker oxides from surfaces or even from internal portions of layers.

Abstract: Multilayer probe structures for testing semiconductor die are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments the structures may include generally helical shaped configurations, helical shape configurations with narrowing radius as the probe extends outward from a substrate, bellows-like configurations, and the like. In some embodiments arrays of multiple probes are provided.

Abstract: Embodiments of the present invention are directed to the formation of microprobe tips elements having a variety of configurations. In some embodiments tips are formed from the same building material as the probes themselves, while in other embodiments the tips may be formed from a different material and/or may include a coating material. In some embodiments, the tips are formed before the main portions of the probes and the tips are formed in proximity to or in contact with a temporary substrate.

Abstract: Multilayer test probe structures are electrochemically fabricated via depositions of one or more materials in a plurality of overlaying and adhered layers. In some embodiments each probe structure may include a plurality of contact arms or contact tips that are used for contacting a specific pad or plurality of pads wherein the arms and/or tips are configured in such away so as to provide a scrubbing motion (e.g. a motion perpendicular to a primary relative movement motion between a probe carrier and the IC) as the probe element or array is made to contact an IC, or the like, and particularly when the motion between the probe or probes and the IC occurs primarily in a direction that is perpendicular to a plane of a surface of the IC. In some embodiments arrays of multiple probes are provided and even formed in desired relative position simultaneously.