Abstract: An electromagnetic interference shield having a main enclosure and optionally at least one auxiliary enclosure. The auxiliary enclosure and the main enclosure have an interior that is continuous with each other. The auxiliary enclosure is made of elastic Faraday material. The outer layer and inner layer may be transparent to view the electronic device. An auxiliary cable with filtering mechanisms may be provided inside a sleeve to allow access and transfer of data from the electronic device while still in the main enclosure.

Abstract: An electromagnetic interference shield enclosure with an extended edge defining a sleeve, the enclosure and sleeve having an outer protective layer and an inner shielding layer to shield electronic devices from electromagnetic interference. The outer layer and inner layer may be transparent to view the electronic device. A magnet system may be provided to allow the device to be operated while in the enclosure. The auxiliary cable with filtering mechanisms may be provided inside the sleeve to allow access and transfer of data from the electronic device while still in the enclosure.

Abstract: An electromagnetic interference shield enclosure with an extended edge defining a sleeve, the enclosure and sleeve having an outer protective layer and an inner shielding layer to shield electronic devices from electromagnetic interference. The outer layer and inner layer may be transparent to view the electronic device. A magnet system may be provided to allow the device to be operated while in the enclosure. The auxiliary cable with filtering mechanisms may be provided inside the sleeve to allow access and transfer of data from the electronic device while still in the enclosure.

Abstract: A micro-cavity resonator including a micro-cavity having a doped sol gel layer or solution applied thereto. The dopant can be various rare earth elements, such as erbium. The micro-cavity can be a spherical or disk or toroid shaped micro-cavity. Certain cavities are capable of high and ultra-high Q factors. Optical energy travels along an inner surface of the coated micro-cavity at a wavelength influenced or determined by the dopant in the coating.

Abstract: Polymer micro-resonators and methods of fabricating the same. A liquid polymer material is applied to a micro-resonator master that includes at least one micro-resonator, such as a disk or toroid micro-resonator. The liquid molding material is cured or set to form a mold that is derived from the master. A replica of the master micro-resonator is cast using the mold, and the replicated micro-toroid resonator(s) are separated from the mold. The polymer micro-resonators can have Q factors up to about 5×106. The mold and replica materials can be a silicone material, such as polydimethylsiloxane.