Abstract: The disclosure belongs to the technical field of Graphic Processing Unit (GPU) chip design, and particularly relates to a texture mapping hardware accelerator based on a double Buffer architecture. The texture mapping hardware accelerator includes an address calculation unit configured for calculating according to different texture address requests to obtain an address for accessing texel cache, a texel cache unit configured to obtain texels of corresponding cache lines from memory according to different request addresses, and a data calculation unit configured to carry out filtering processing according to different isotropic and anisotropic filtering modes and pixel processing for border_color and swizzle operation. With double Buffers, the calculation efficiency of texture index addresses may be improved, and when two layers of data need to be calculated at the same time, calculation may be started in parallel at the same time.

Abstract: A method of fabricating pre-structured functional wafers, pre-structured functional cuboid or wafer stack, and a method of fabricating an array of functional multilayer stack actuators made of relaxor ferroelectric single crystal piezoelectric thin layers comprising sequentially repeated steps of wafer dicing and trench refilling into relatively thick wafer(s). A bulk-micromachined dimensioned deformable mirror device comprising a base supporting substrate, a plurality of stack actuators that is made by segmenting a pre-structured relaxor ferroelectric single crystal piezoelectric cuboid or wafer stack, a plurality of pedestals disposed on the plurality of stack actuators; a deformable membrane mirror mounted on said pedestals; and a plurality of addressable electrode contacts.

Abstract: MEMS hierarchically-dimensioned optical mirrors, each comprising a substrate, a plurality of spacers disposed on the substrate, a plurality of piezoelectric/electrostrictive cantilever microactuators disposed on the plurality of spacers, and a monolithic deformable mirror or a segmented mirror array disposed on the plurality of the cantilever assemblies, having significantly improved overall device performances owing to the use of the cantilever microactuators based on relaxor ferroelectric single crystal materials and/or other piezoelectric/electrostrictive materials, are disclosed along with methods of manufacturing such devices.

Abstract: A MEMS hierarchically-dimensioned deformable mirror comprising a substrate, a plurality of spacers disposed on the substrate, a plurality of piezoelectric cantilever microactuators disposed on the plurality of spacers, and a continuous deformable membrane disposed on the plurality of the cantilever assemblies, has significantly improved overall device performances owing to the use of the cantilever microactuators based on relaxor ferroelectric single crystal materials or other piezoelectric materials.

Abstract: A MEMS hierarchically-dimensioned deformable minor comprising a substrate, a plurality of spacers disposed on the substrate, a plurality of piezoelectric cantilever microactuators disposed on the plurality of spacers, and a continuous deformable membrane disposed on the plurality of the cantilever assemblies, has significantly improved overall device performances owing to the use of the cantilever microactuators based on relaxor ferroelectric single crystal materials or other piezoelectric materials.

Abstract: A method of fabricating micro- and nano-scale fiber comprises: spreading micro- and nano-scale particles into a liquid or fluid-like material prior to forcing portions of the liquid or fluid-like material that surround the particles to depart from the original liquid or fluid-like environment by using a force field; stretching to elongate the portions of the liquid or fluid-like material until the free ends of the stretched portions stop motion to complete fiber or fiber-like structures in micro- and nano-scales.

Abstract: A high angular deflection micro-mirror system including a substrate, a spacer structure extending from the substrate, a deformable membrane supported by the spacer structure, one or more supports located off center on the deformable membrane, and one or more mirrors on the support cantilevered therefrom to achieve a high angular deflection of the mirrors as the deformable membranes deform.

Abstract: A high angular deflection micro-mirror system including a substrate, a spacer structure extending from the substrate, a deformable membrane supported by the spacer structure, one or more supports located off center on the deformable membrane, and one or more mirrors on the support cantilevered therefrom to achieve a high angular deflection of the mirrors as the deformable membranes deform.

Abstract: A tunable optical filter including at least one deformable membrane actuator. The actuator may include an array of a thousand or millions of individual actuator cells for strength and mechanical robustness. The deformable membrane actuator including a first primary substrate having a first optical portion, an electrically conductive and deformable membrane, an electrically conductive primary substrate electrode and a membrane support structure. The substrate electrode and the membrane support structure are disposed on or adjacent to the first primary substrate, the deformable membrane being supported by the membrane support structure, and a second substrate having a second optical portion. The second substrate is supported by a load support structure disposed on one surface of the deformable membrane and is located a distance from the first substrate.

Abstract: A tunable optical filter including at least one deformable membrane actuator. The actuator may comprise an array of a thousand or millions of individual actuator cells for strength and mechanical robustness. The deformable membrane actuator including a first primary substrate having a first optical portion, an electrically conductive and deformable membrane, an electrically conductive primary substrate electrode and a membrane support structure. The substrate electrode and the membrane support structure are disposed on or adjacent to the first primary substrate, the deformable membrane being supported by the membrane support structure, and a second substrate having a second optical portion. The second substrate is supported by a load support structure disposed on one surface of the deformable membrane and is located a distance from the first substrate.