Abstract: A virtual reality/augmented reality (VR/AR) headset system (including the capability for one or both of virtual reality and augmented reality) includes a remote optical engine. The remote disposition of the optical engine removes many or all of the components of the VR/AR headset system that add weight, heat, and other characteristics that can add to user discomfort in using the system from the headset. An electronic image is received and/or generated remotely at the optical engine, and is transmitted optically from the remote location to the headset to be viewed by the user. One or more optical waveguides may be used to transmit the electronic image to one or more passive displays of the headset, from the remote optical engine.

Abstract: Apparatus and method relating generally to electronics are disclosed. In one such an apparatus, a film assembly has an upper surface and a lower surface opposite the upper surface. A dielectric film of the film assembly has a structured profile along the upper surface or the lower surface for having alternating ridges and grooves in a corrugated section in an at rest state of the film assembly. Conductive traces of the film assembly conform to the upper surface or the lower surface in or on the dielectric film in the corrugated section.

Abstract: Embedded organic interposers for high bandwidth are provided. Example embedded organic interposers provide thick conductors with more dielectric space, and more routing layers of such conductors than conventional interposers, in order to provide high bandwidth transmission capacity over longer spans. The embedded organic interposers provide high bandwidth transmission paths between components such as HBM, HBM2, and HBM3 memory stacks, and other components. To provide the thick conductors and more routing layers for greater transmission capacity, extra space is achieved by embedding the organic interposers in the core of the package. Example embedded organic interposers lower a resistive-capacitive (RC) load of the routing layers to provide improved signal transmission of 1-2 GHz up to 20-60 GHz bandwidth for each 15 mm length, for example. The embedded organic interposers are not limited to use with memory modules.

Abstract: A microelectronic assembly including an insulating layer having a plurality of nanoscale conductors disposed in a nanoscale pitch array therein and a pair of microelectronic elements is provided. The nanoscale conductors can form electrical interconnections between contacts of the microelectronic elements while the insulating layer can mechanically couple the microelectronic elements together.

Abstract: A microelectronic assembly including first and second laminated microelectronic elements is provided. A patterned bonding layer is disposed on a face of each of the first and second laminated microelectronic elements. The patterned bonding layers are mechanically and electrically bonded to form the microelectronic assembly.

Abstract: Dies-on-package devices and methods therefor are disclosed. In a dies-on-package device, a first IC die is surface mount coupled to an upper surface of a package substrate. Conductive lines are coupled to the upper surface of the package substrate in a fan-out region with respect to the first IC die. A molding layer is formed over the upper surface of the package substrate, around sidewall surfaces of the first IC die, and around bases and shafts of the conductive lines. A plurality of second IC dies is located at a same level above an upper surface of the molding layer respectively surface mount coupled to sets of upper portions of the conductive lines. The plurality of second IC dies are respectively coupled to the sets of the conductive lines in middle third portions respectively of the plurality of second IC dies for corresponding fan-in regions thereof.

Abstract: A method of fabricating a semiconductor assembly can include providing a semiconductor element having a front surface, a rear surface, and a plurality of conductive pads, forming at least one hole extending at least through a respective one of the conductive pads by processing applied to the respective conductive pad from above the front surface, forming an opening extending from the rear surface at least partially through a thickness of the semiconductor element, such that the at least one hole and the opening meet at a location between the front and rear surfaces, and forming at least one conductive element exposed at the rear surface for electrical connection to an external device, the at least one conductive element extending within the at least one hole and at least into the opening, the conductive element being electrically connected with the respective conductive pad.

Abstract: Vertical capacitors for microelectronics are provided. An example thin capacitor layer can provide one or numerous capacitors to a semiconductor chip or integrated circuit. In an implementation, a thin capacitor layer of 50-100 ?m thickness may have 5000 vertically disposed capacitor plates per linear centimeter, while occupying only a thin slice of the package. Electrodes for each capacitor plate are accessible at multiple surfaces. Electrode density for very fine pitch interconnects can be in the range of 2-200 ?m separation between electrodes. A redistribution layer (RDL) may be fabricated on one or both sides of the thin capacitor layer to provide fan-out ball grid arrays that occupy insignificant space. RDLs or through-vias can connect together sets of the interior vertical capacitor plates within a given thin capacitor layer to form various capacitors from the plates to meet the needs of particular chips, dies, integrated circuits, and packages.

Abstract: Embedded vialess bridges are provided. In an implementation, discrete pieces containing numerous conduction lines or wires in a 3-dimensional bridge piece are embedded where needed in a main substrate to provide dense arrays of signal, power, and electrical ground wires below the surface of the main substrate. Vertical conductive risers to reach the surface plane of the main substrate are also included in the discrete piece, for connecting to dies on the surface of the substrate and thereby interconnecting the dies to each other through the dense array of wires in the discrete piece. The discrete piece to be embedded may have parallel planes of conductors at regular intervals within itself, and thus may present a working surface homogeneously covered with the ends of vertical conductors available to connect surface components to each other and to ground and power at many places along the embedded piece.

Abstract: An integrated device package is disclosed. The integrated device package can include an integrated device die, an element, a cavity, and an electrical interconnect. The element can have an antenna structure. The element can be attached to a surface of the integrated device. The cavity can be disposed between the integrated device die and the antenna structure. The electrical interconnect can connect the integrated device die and the antenna structure.

Abstract: An interconnection component includes a first support portion, a second support portion, a redistribution layer and a passive device, wherein at least one of the first and second support portions is comprised of a semiconductor material. The first support portion includes first and second opposed major surfaces and a plurality of first conductive vias extending through the first support portion substantially perpendicular to major surfaces. The second support portion includes first and second opposed major surfaces and a plurality of second conductive vias extending through the second support portion substantially perpendicular to the first and second major surfaces of the second support. The redistribution layer can be disposed between the second surfaces of the first and second support portions. The passive device can be positioned at least partially within the redistribution layer and electrically connected with one or more of the first conductive vias and the second conductive vias.

Abstract: A microelectronic assembly including an insulating layer having a plurality of nanoscale conductors disposed in a nanoscale pitch array therein and a pair of microelectronic elements is provided. The nanoscale conductors can form electrical interconnections between contacts of the microelectronic elements while the insulating layer can mechanically couple the microelectronic elements together.

Abstract: An adhesive with self-connecting interconnects is provided. The adhesive layer provides automatic 3D joining of microelectronic components with a conductively self-adjusting anisotropic matrix. In an implementation, the adhesive matrix automatically makes electrical connections between two surfaces that have opposing electrical contacts, and bonds the two surfaces together. Conductive members in the adhesive matrix are aligned to automatically establish electrical connections between at least partially aligned contacts on each of the two surfaces while providing nonconductive adhesion between parts of the two surfaces lacking aligned contacts. An example method includes forming an adhesive matrix between two surfaces to be joined, including conductive members anisotropically aligned in an adhesive medium, then pressing the two surfaces together to automatically connect corresponding electrical contacts that are at least partially aligned on the two surfaces.

Abstract: A method for making an interposer includes forming a plurality of wire bonds bonded to one or more first surfaces of a first element. A dielectric encapsulation is formed contacting an edge surface of the wire bonds which separates adjacent wire bonds from one another. Further processing comprises removing at least portions of the first element, wherein the interposer has first and second opposite sides separated from one another by at least the encapsulation, and the interposer having first contacts and second contacts at the first and second opposite sides, respectively, for electrical connection with first and second components, respectively, the first contacts being electrically connected with the second contacts through the wire bonds.

Abstract: A three-dimensional stacking technique performed in a wafer-to-wafer fashion reducing the machine movement in production. The Wafers are processed with metallic traces and stacked before dicing into separate die stacks. The traces of each layer of the stacks are interconnected via electroless plating.

Abstract: A foldable microelectronic assembly and a method for forming the same are provided. One or more packages comprising encapsulated microelectronic elements are formed, along with a compliant layer. The packages and the compliant layer are coupled to a redistribution layer. The compliant layer and the redistribution layer are bent such that the redistribution layer is non-planar.

Abstract: An interconnect element includes a semiconductor or insulating material layer that has a first thickness and defines a first surface; a thermally conductive layer; a plurality of conductive elements; and a dielectric coating. The thermally conductive layer includes a second thickness of at least 10 microns and defines a second surface of the interconnect element. The plurality of conductive elements extend from the first surface of the interconnect element to the second surface of the interconnect element. The dielectric coating is between at least a portion of each conductive element and the thermally conductive layer.

Abstract: A component can include a substrate having a front surface and a rear surface remote therefrom, an opening extending from the rear surface towards the front surface, and a conductive via extending within the opening. The substrate can have a CTE less than 10 ppm/° C. The opening can define an inner surface between the front and rear surfaces. The conductive via can include a first metal layer overlying the inner surface and a second metal region overlying the first metal layer and electrically coupled to the first metal layer. The second metal region can have a CTE greater than a CTE of the first metal layer. The conductive via can have an effective CTE across a diameter of the conductive via that is less than 80% of the CTE of the second metal region.

Abstract: A microelectronic assembly including first and second laminated microelectronic elements is provided. A patterned bonding layer is disposed on a face of each of the first and second laminated microelectronic elements. The patterned bonding layers are mechanically and electrically bonded to form the microelectronic assembly.

Abstract: A component includes a substrate and a capacitor formed in contact with the substrate. The substrate can consist essentially of a material having a coefficient of thermal expansion of less than 10 ppm/° C. The substrate can have a surface and an opening extending downwardly therefrom. The capacitor can include at least first and second pairs of electrically conductive plates and first and second electrodes. The first and second pairs of plates can be connectable with respective first and second electric potentials. The first and second pairs of plates can extend along an inner surface of the opening, each of the plates being separated from at least one adjacent plate by a dielectric layer. The first and second electrodes can be exposed at the surface of the substrate and can be coupled to the respective first and second pairs of plates.