Abstract: Incorporating at least one magnetic alignment structure on a microelectronic device and incorporating at least one alignment coil within a microelectronic substrate, wherein the alignment coil may be powered to form a magnetic field to attract the magnetic alignment structure, thereby aligning the microelectronic device to the microelectronic substrate. After alignment, the microelectronic device may be electrically attached to the substrate. Embodiments may include additionally incorporating an alignment detection coil within the microelectronic substrate, wherein the alignment detection coil may be powered to form a magnetic field to detect variations in the magnetic field generated by the alignment coil in order verify the alignment of the microelectronic device to the microelectronic substrate.

Abstract: Incorporating at least one magnetic alignment structure on a microelectronic device and incorporating at least one alignment coil within a microelectronic substrate, wherein the alignment coil may be powered to form a magnetic field to attract the magnetic alignment structure, thereby aligning the microelectronic device to the microelectronic substrate. After alignment, the microelectronic device may be electrically attached to the substrate. Embodiments may include additionally incorporating an alignment detection coil within the microelectronic substrate, wherein the alignment detection coil may be powered to form a magnetic field to detect variations in the magnetic field generated by the alignment coil in order verify the alignment of the microelectronic device to the microelectronic substrate.

Abstract: Techniques for scale factor based on viewing distance are described. In at least some embodiments, a viewing distance refers to a distance at which a user typically views and/or is viewing a display device. For instance, different displays can be used in different ways and for different purposes, and thus may have different viewing distances. Techniques discussed herein consider the estimated viewing distance of a particular display in determining a scale factor to be applied to visual elements (e.g., graphics) for output via the particular display. A scale factor, for instance, can specify that visual elements are to zoomed-out or zoomed-in prior to be displayed. As detailed herein, this enables a consistent viewing experience to be maintained across different devices with different display sizes and different viewing distances.

Abstract: Incorporating at least one magnetic alignment structure on a microelectronic device and incorporating at least one alignment coil within a microelectronic substrate, wherein the alignment coil may be powered to form a magnetic field to attract the magnetic alignment structure, thereby aligning the microelectronic device to the microelectronic substrate. After alignment, the microelectronic device may be electrically attached to the substrate. Embodiments may include additionally incorporating an alignment detection coil within the microelectronic substrate, wherein the alignment detection coil may be powered to form a magnetic field to detect variations in the magnetic field generated by the alignment coil in order verify the alignment of the microelectronic device to the microelectronic substrate.

Abstract: Incorporating at least one magnetic alignment structure on a microelectronic device and incorporating at least one alignment coil within a microelectronic substrate, wherein the alignment coil may be powered to form a magnetic field to attract the magnetic alignment structure, thereby aligning the microelectronic device to the microelectronic substrate. After alignment, the microelectronic device may be electrically attached to the substrate. Embodiments may include additionally incorporating an alignment detection coil within the microelectronic substrate, wherein the alignment detection coil may be powered to form a magnetic field to detect variations in the magnetic field generated by the alignment coil in order verify the alignment of the microelectronic device to the microelectronic substrate.

Abstract: A neuro-probe device is provided. The neuro-probe device includes a carrier including bio-resorbable glass, and a neuro-probe mounted on the carrier.

Abstract: Techniques for scale factor based on viewing distance are described. In at least some embodiments, a viewing distance refers to a distance at which a user typically views and/or is viewing a display device. For instance, different displays can be used in different ways and for different purposes, and thus may have different viewing distances. Techniques discussed herein consider the estimated viewing distance of a particular display in determining a scale factor to be applied to visual elements (e.g., graphics) for output via the particular display. A scale factor, for instance, can specify that visual elements are to zoomed-out or zoomed-in prior to be displayed. As detailed herein, this enables a consistent viewing experience to be maintained across different devices with different display sizes and different viewing distances.