Abstract: An optical data storage and retrieval system uses a flying head. The flying head is supported on a moving media having information stored in a plurality of stored data locations thereon. Information is stored in each of the plurality of media locations as physical structures capable of modulating the polarization state of incident light into one of two output polarization states. The flying head includes an optical processing assembly which directs an incident light beam having a source polarization state onto the moving media, accessing successive data locations. A reflected light beam having the source polarization state of the incident light beam modulated by a respective polarization modifying data location into one of the output polarization states is received by the flying head.

Abstract: A multiphoton photorefractive holographic recording material includes an electro-optic host material doped with at least one lanthanide.

Abstract: An optical system and method for transmission of light between a RF modulated source of light and a magneto-optical storage location along an optical path including: orthogonally aligned first and second single-mode polarization maintaining optical fibers, a flying magneto-optical head, and a quarter-wave plate positioned on the flying magneto-optical head.

Abstract: The present invention describes a method for high capacity holographic data storage in photorefractive crystals. A doped ferroelectric crystal is used as a data storage medium. Prior to the recording, the crystal is depoled either thermally or electrically. Multiplexed photorefractive holograms are then recorded by illuminating the crystal in such a manner that domain screening of the photorefractive space-charge field occurs. The crystal is then repoled to enable the reading of the holograms stored within the crystal. Finally, any given hologram is readout by illuminating the crystal at the Bragg condition, which typically occurs while illuminating the crystal at the same angle and/or wavelength at which the hologram was recorded.

Abstract: A multiphoton photorefractive holographic recording material includes an electro-optic host material doped with at least one lanthanide.

Abstract: A hologram with a dynamically controlled diffraction efficiency and enhanced signal-to-noise ratio is recorded in ferroelectric photorefractive materials, such as strontium barium niobate (Sr.sub.x Ba.sub.1-x Nb.sub.2 O.sub.6) (SBN), BSTN, SCNN, PBN, BSKNN, BaTiO.sub.3, LiNbO.sub.3, KNbO.sub.3, KTN, PLZT and the tungsten bronze family. The diffraction efficiency of the hologram is dynamically controlled by applying an electric field along the polar axis of the ferroelectric photorefractive recording medium. Electrically controlled diffraction is used in conjunction with hologram fixing and operation of the material at a temperature in the vicinity of or above its Curie temperature to additionally provide prolonged, low-noise readout. The general methods for recording and reconstructing a hologram (or a set of multiplexed holograms) using these techniques is disclosed.