A multi-die module includes a first die with a first device and a second die with a second device. The multi-die module also includes a contactless coupler configured to convey signals between the first device and the second device. The multi-die module also includes a coupling loss reduction structure.

An electronic device includes an interconnect layer, a second chip and a third chip provided on a first side of the interconnect layer, and a first chip provided on a second side of the interconnect layer. The interconnect layer includes conductive members connecting between the first chip and the second chip, and connecting between the first chip and the third chip, respectively. The interconnect layer does not include a conductive member directly connecting between the second chip and the third chip.

Capacitive couplings in a direct-bonded interface for microelectronic devices are provided. In an implementation, a microelectronic device includes a first die and a second die direct-bonded together at a bonding interface, a conductive interconnect between the first die and the second die formed at the bonding interface by a metal-to-metal direct bond, and a capacitive interconnect between the first die and the second die formed at the bonding interface. A direct bonding process creates a direct bond between dielectric surfaces of two dies, a direct bond between respective conductive interconnects of the two dies, and a capacitive coupling between the two dies at the bonding interface. In an implementation, a capacitive coupling of each signal line at the bonding interface comprises a dielectric material forming a capacitor at the bonding interface for each signal line. The capacitive couplings result from the same direct bonding process that creates the conductive interconnects direct-bonded together at the same bonding interface.

According to one embodiment, the interconnect layer includes a fourth conductive member and a fifth conductive member. The fourth conductive member is provided between the first region of the first chip and the third region of the second chip. The fourth conductive member connects the first conductive member of the first chip and the second conductive member of the second chip. The fifth conductive member is provided between the second region of the first chip and the fifth region of the third chip. The fifth conductive member connects the first conductive member of the first chip and the third conductive member of the third chip. The first chip is provided between the first terminal and the second terminal.

The present invention relates generally to compositions for use in biological and chemical separations, as well as other applications. More specifically, the present invention relates to hybrid felts fabricated from electrospun nanofibers with high permeance and high capacity. Such hybrid felts utilize derivatized cellulose, and at least one non-cellulose-based polymer that may be removed from the felt by subjecting it to moderately elevated temperatures and/or solvents capable of dissolving the non-cellulose-based polymer to leave behind a porous nanofiber felt having more uniform pore sizes and other enhanced properties when compared to single component nanofiber felts.

A wafer structure, a method for manufacturing the same and a chip structure are provided. A first capacitor plate is arranged in a first chip, a second capacitor plate is arranged in a second chip, and the first chip is stacked together via bonding layers with the second chip with a front surface of the first chip facing toward a front surface of the second chip. In this way, a capacitor structure formed by the first capacitor plate, the second capacitor plate and dielectric materials provided therebetween is formed while bonding the first chip and second chip together, and the capacitor plate and the dielectric materials may be formed while forming a device interconnection structure in the chip, such that no additional process is required, thereby improving device integration and process integration.

An electronic chip, chip assembly, device, system, and method enabling tracked data communications. The electronic chip comprises a plurality of processing cores and at least one hardware interface coupled to at least one of the one or more processing cores. At least one processing core implements a game and/or simulation engine, at least one processing core implements a position engine, and at least one processing core implements a gyroscope and, optionally, an IMU. The at least one position engine obtains pose data from an external positioning system comprising GNSS augmented by millimeter-wave cellular networks and/or Wi-Fi; and internal pose data from the gyroscope, optional IMU, and game and/or simulation engine, the data comprising inertial, 3D structure, and simulation data, thereby computing a 6 DOF pose of the client device, driving processing of 3D applications by the one or more game and/or simulation engine.

A system for interconnecting at least two die each die having a plurality of conducting layers and dielectric layers disposed upon a substrate which may include active and passive elements. In one embodiment there is at least one interconnect coupling at least one conducting layer on a side of one die to at least one conducting layer on a side of the other die. Another interconnect embodiment is a slug having conducting and dielectric layers disposed between two or more die to interconnect between the die. Other interconnect techniques include direct coupling such as rod, ball, dual balls, bar, cylinder, bump, slug, and carbon nanotube, as well as indirect coupling such as inductive coupling, capacitive coupling, and wireless communications. The die may have features to facilitate placement of the interconnects such as dogleg cuts, grooves, notches, enlarged contact pads, tapered side edges and stepped vias.

A semiconductor device includes a substrate, a plurality of circuit elements on a front side of the substrate, and a first substantially spiral-shaped conductor on a back side of the substrate is provided. The device further includes a first through-substrate via (TSV) electrically connecting a first end of the substantially spiral-shaped conductor to a first one of the plurality of circuit elements, and a second TSV electrically connecting a second end of the substantially spiral-shaped conductor to a second one of the plurality of circuit elements. The device may be a package further including a second die having a front side on which is disposed a second substantially spiral-shaped conductor. The front side of the second die is disposed facing the back side of the substrate, such that the first and second substantially spiral-shaped conductors are configured to wirelessly communicate.

An integrated circuit (IC) package includes a first die with a first surface overlaying a substrate. The first die includes a first metal pad at a second surface opposing the first surface. The IC package also includes a dielectric layer having a first surface contacting the second surface of the first die. The IC package further includes a second die with a surface that contacts a second surface of the dielectric layer. The second die includes a second metal pad aligned with the first metal pad of the first die. A plane perpendicular to the second surface of the first die intersects the first metal pad and the second metal pad.