Abstract: A holographic imaging system may include an optical source configured to output a source beam and a splitter configured to split the source beam into a reference beam and an object beam that may be incident on a target to form a scattered object beam. The system may also include a combiner configured to combine the filtered scattered object beam with the reference beam to form an interference beam, an imaging array configured to receive the interference beam and generate frames of raw holographic data based on measurements of the interference beam over time, and an image data processor. The image data processor may be configured to receive the frames of raw holographic data from the imaging array, remove data components within the frames that are associated with the particle motion having a motion frequency that is less than a movement frequency threshold to form conditioned raw holographic data, and generate an image based on the conditioned raw holographic data.

Abstract: A holographic imaging system may include an optical source configured to output a source beam, a splitter configured to split the source beam into a reference beam and an object beam that is incident on a target to form a scattered object beam, and a pre-filter comprising a telecentric lens and a spatial filter. The pre-filter may be configured to receive the scattered object beam and filter diffuse light from the scattered object beam to form a filtered scattered object beam. The system may also include a combiner configured to combine the filtered scattered object beam with the reference beam to form an interference beam, and an imaging array configured to receive the interference beam and generate raw holographic data based on the interference beam.

Abstract: A magnetic pouch attachment mechanism may include one or more magnetic pouch mounts having an alignment plate with one or more magnetic areas disposed within the alignment plate. The magnetic pouch mount may also include a pouch that may be removably coupled with the one or more magnetic pouch mounts such that when the pouch is placed in proximity to the one or more magnetic pouch mounts, an attractive magnetic force is exerted between the pouch and the one or more magnetic pouch mounts such that the pouch aligns with and couples to the one or more magnetic pouch mounts. A mounting bracket coupled to the pouch may include one or more bracket magnetic areas disposed within the mounting bracket and configured to induce an attractive magnetic force with the one or more magnetic areas.

Abstract: A magnetic pouch attachment mechanism includes one or more magnetic pouch mounts (500) having an alignment plate (505) with one or more magnetic areas (520) disposed within the alignment plate (505). The magnetic pouch mount (500) also includes a pouch (900) removably coupled with the one or more magnetic pouch mounts (500) such that when the pouch (900) is placed in proximity to the one or more magnetic pouch mounts (500), an attractive magnetic force is exerted between the pouch (900) and the one or more magnetic pouch mounts (500) such that the pouch (900) aligns with and couples to the one or more magnetic pouch mounts (500). A mounting bracket (920) coupled to the pouch (900) includes one or more bracket magnetic areas (935) disposed within the mounting bracket (920) and configured to induce an attractive magnetic force with the one or more magnetic areas (520).

Abstract: A holographic imaging system may include an optical source configured to output a source beam and a splitter configured to split the source beam into a reference beam and an object beam that may be incident on a target to form a scattered object beam. The system may also include a combiner configured to combine the filtered scattered object beam with the reference beam to form an interference beam, an imaging array configured to receive the interference beam and generate frames of raw holographic data based on measurements of the interference beam over time, and an image data processor. The image data processor may be configured to receive the frames of raw holographic data from the imaging array, remove data components within the frames that are associated with the particle motion having a motion frequency that is less than a movement frequency threshold to form conditioned raw holographic data, and generate an image based on the conditioned raw holographic data.

Abstract: A holographic imaging system may include an optical source configured to output a source beam, a splitter configured to split the source beam into a reference beam and an object beam that is incident on a target to form a scattered object beam, and a pre-filter comprising a telecentric lens and a spatial filter. The pre-filter may be configured to receive the scattered object beam and filter diffuse light from the scattered object beam to form a filtered scattered object beam. The system may also include a combiner configured to combine the filtered scattered object beam with the reference beam to form an interference beam, and an imaging array configured to receive the interference beam and generate raw holographic data based on the interference beam.

Abstract: Container mounting assemblies are disclosed. According to one embodiment, a container mounting assembly includes mounting plates (31, 33), track engagement members outwardly extending from the track engagement surface, mounting receptacles (20, 20?) spaced and outwardly extending from the container mounting surface (3), and a retention locking member (40) near at least one mounting receptacles. Each mounting plate has a track engagement surface and a container mounting surface opposite the track engagement surface. The track engagement members can engage one or more track slots of a track member. Each mounting receptacle has at least one vertical slot (17) for receiving an insert of a container. The retention locking member is configured to secure the container to the container mounting surface.

Abstract: Container mounting assemblies are disclosed. According to one embodiment, a container mounting assembly includes mounting plates (31, 33), track engagement members outwardly extending from the track engagement surface, mounting receptacles (20, 20?) spaced and outwardly extending from the container mounting surface (3), and a retention locking member (40) near at least one mounting receptacles. Each mounting plate has a track engagement surface and a container mounting surface opposite the track engagement surface. The track engagement members can engage one or more track slots of a track member. Each mounting receptacle has at least one vertical slot (17) for receiving an insert of a container. The retention locking member is configured to secure the container to the container mounting surface.

Abstract: A magnetic pouch attachment mechanism includes one or more magnetic pouch mounts (500) having an alignment plate (505) with one or more magnetic areas (520) disposed within the alignment plate (505). The magnetic pouch mount (500) also includes a pouch (900) removably coupled with the one or more magnetic pouch mounts (500) such that when the pouch (900) is placed in proximity to the one or more magnetic pouch mounts (500), an attractive magnetic force is exerted between the pouch (900) and the one or more magnetic pouch mounts (500) such that the pouch (900) aligns with and couples to the one or more magnetic pouch mounts (500). A mounting bracket (920) coupled to the pouch (900) includes one or more bracket magnetic areas (935) disposed within the mounting bracket (920) and configured to induce an attractive magnetic force with the one or more magnetic areas (520).

Abstract: A test device applies a defined mechanical load to a soft biomaterial such as a cell culture and a microscope forms a volume image data set showing the strain field or displacement field occurring in the medium. The data set is processed to determine fundamental mechanical properties of the cell, its interaction with the surrounding medium, or its responses loading or deformation of its surrounding medium. The device may also be used to calibrate or determine fundamental mechanical properties of the medium. The device includes a linear actuator that bears against the specimen, and adapted for a volume imaging device such as a scanning laser confocal microscope that forms a volume image data set of the specimen. The specimen may be supported in a Petri dish and is preferably imaged from below by an inverted microscope. Preferably the actuator device attaches to or forms the specimen stage of microscope.

Abstract: Method and systems provide growth of polymer structures at a high rate in a selective manner. In various embodiments, the method or system can expose the growth site to a polymer source and growing a polymer tube at a rate of at least 80 micrometer per hour at the growth site. The method or system can provide selectivity by providing a growth site on a substrate by patterning a metal, such as copper, that provides a seed site for the polymer. Non-selected sites can be coated with a polymer growth inhibitor, such as polyimide or silicon nitride.

Abstract: Method and systems provide growth of polymer structures at a high rate in a selective manner. In various embodiments, the method or system can expose the growth site to a polymer source and growing a polymer tube at a rate of at least 80 micrometer per hour at the growth site. The method or system can provide selectivity by providing a growth site on a substrate by patterning a metal, such as copper, that provides a seed site for the polymer. Non-selected sites can be coated with a polymer growth inhibitor, such as polyimide or silicon nitride.

Abstract: Method and systems provide growth of polymer structures at a high rate in a selective manner. In various embodiments, the method or system can expose the growth site to a polymer source and growing a polymer tube at a rate of at least 80 micrometer per hour at the growth site. The method or system can provide selectivity by providing a growth site on a substrate by patterning a metal, such as copper, that provides a seed site for the polymer. Non-selected sites can be coated with a polymer growth inhibitor, such as polyimide or silicon nitride.

Abstract: Method and systems provide growth of polymer structures at a high rate in a selective manner. In various embodiments, the method or system can expose the growth site to a polymer source and growing a polymer tube at a rate of at least 80 micrometer per hour at the growth site. The method or system can provide selectivity by providing a growth site on a substrate by patterning a metal, such as copper, that provides a seed site for the polymer. Non-selected sites can be coated with a polymer growth inhibitor, such as polyimide or silicon nitride.

Abstract: Disclosed is a method and apparatus for bonding sheets together without trapping bubbles between two adjacent sheets and a procedure for easy detachment of the completed stack of bonded together sheets from the apparatus that constructed it. The present invention is particularly well suited for use with apparatus for construction of three-dimensional objects from a stack of thin sheets bonded together.

Abstract: Disclosed is a method and apparatus for bonding sheets together without trapping bubbles between two adjacent sheets and a procedure for easy detachment of the completed stack of bonded together sheets from the apparatus that constructed it. The present invention is particularly well suited for use with apparatus for construction of three-dimensional objects from a stack of thin sheets bonded together.

Abstract: A Seek and Scan Probe (SSP) memory device is disclosed. The memory device includes a moving part having microelectromechanical (MEMS) structures fabricated on a first wafer and CMOS and memory medium components fabricating on a second wafer bonded to the first wafer.

Abstract: A suspension lug for releasably suspends loads under aircraft. The suspension lug has a lug eye and a threaded base and a rotation mechanism is inserted into the threaded portion. When the suspension lug is threaded into a compatible well in the load and the load is released from the aircraft, the rotation mechanism causes the suspension lug to rotate by ninety degrees from an initial orientation in which the face of the lug eye is pointed in the direction of flight to a final orientation in which the edge of the lug eye is pointed in the direction of flight. The rotation of the lug eye significantly reduces the drag on the load. Also described are methods of manufacturing and using the suspension lug of the invention.

Abstract: “An interconnection device comprises a Systems In Package (SIP) device, or Systems in Chip (SIC) device, including one or more embedded vias extending through a base substrate. A process to produce the interconnection device.