Abstract: Embodiments may be generally directed to techniques to utilize a protocol adaption layer (PAL) extension based on the bus protocol to enable a wireless transfer of data between a persistent storage device and a remote device and communicate, via a transceiver, the data as radio-frequency (RF) signals between the persistent storage device and the remote device utilizing the PAL extension.

Abstract: Embodiments may be generally directed to techniques to utilize a protocol adaption layer (PAL) extension based on the bus protocol to enable a wireless transfer of data between a persistent storage device and a remote device and communicate, via a transceiver, the data as radio-frequency (RF) signals between the persistent storage device and the remote device utilizing the PAL extension.

Abstract: Embodiments of a folded meta-inspired antenna for dual-band operation and user equipment for dual-band operation in a wireless network are generally described herein. In some embodiments, the folded meta-inspired antenna may include first and second conductive layers disposed on opposite sides of a substrate to provide a wideband distributed structure comprising a plurality of high-Q resonances resulting from, at least in part, metamaterial-based loading. Conductive material on the first side of the substrate is arranged around a central longitudinal slot coupled with a plurality of perpendicular slots. For dual-band operation, the folded meta-inspired antenna may operate as a folded monopole at a higher frequency band and operate as a slot-type radiator at a lower frequency band. The plurality of resonances may cause the folded meta-inspired antenna to achieve broader bandwidth at both lower and higher frequency bands.

Abstract: Embodiments of millimeter-wave antenna structures are generally described herein. The antenna structure may include an a radiating-element layer comprising a patterned conductive material, a ground layer comprising conductive material disposed on a dielectric substrate, and a feed-line layer comprising conductive material disposed on a dielectric substrate. In some embodiments, the antenna structure may include an air-gap layer disposed between the radiating-element layer and the ground layer. The air-gap layer may include spacing elements to separate the radiating-element layer and the ground layer by a predetermined distance. In some other embodiments, the radiating-element layer may be disposed on a radiating-element dielectric substrate which may include one or more cavities between the radiating-element layer and the ground layer.

Abstract: Embodiments of a folded meta-inspired antenna for dual-band operation and user equipment for dual-band operation in a wireless network are generally described herein. In some embodiments, the folded meta-inspired antenna may include first and second conductive layers disposed on opposite sides of a substrate to provide a wideband distributed structure comprising a plurality of high-Q resonances resulting from, at least in part, metamaterial-based loading. Conductive material on the first side of the substrate is arranged around a central longitudinal slot coupled with a plurality of perpendicular slots. For dual-band operation, the folded meta-inspired antenna may operate as a folded monopole at a higher frequency band and operate as a slot-type radiator at a lower frequency band. The plurality of resonances may cause the folded meta-inspired antenna to achieve broader bandwidth at both lower and higher frequency bands.