Abstract: A system may include an inflatable assembly having a plurality of members. The system may also include a plurality of sensors disposed at a plurality of positions inside or around the inflatable assembly, such that the plurality of sensors may acquire data related to a shape of the inflatable assembly. The system also includes one or more valves, each configured to direct a fluid into a corresponding member of the plurality of members of the inflatable assembly. The system also includes a processor that adjusts positions of the one or more valves to cause the fluid to be directed into the corresponding member of the plurality of members of the inflatable assembly based on the data and a desired shape of the inflatable assembly.

Abstract: A system may include a virtual reality system configured to present one or more virtual objects via an electronic display. The system may also include one or more inflatable objects that correspond to the one or more virtual objects, such that the one or more inflatable objects matches one or more shapes of the one or more virtual objects. The system may also include a processor configured to cause at least one of the one or more inflatable objects to inflate based on feedback from the virtual reality system.

Abstract: A system may include an inflatable assembly having a plurality of members. The system may also include a plurality of sensors disposed at a plurality of positions inside or around the inflatable assembly, such that the plurality of sensors may acquire data related to a shape of the inflatable assembly. The system also includes one or more valves, each configured to direct a fluid into a corresponding member of the plurality of members of the inflatable assembly. The system also includes a processor that adjusts positions of the one or more valves to cause the fluid to be directed into the corresponding member of the plurality of members of the inflatable assembly based on the data and a desired shape of the inflatable assembly.

Abstract: An inflatable assembly may include a housing that has a plurality of adjustment inflatables that may form a range of shapes at different levels of inflation. The inflatable may also include one or more sensors disposed on the housing and one or more valves disposed in the housing. The valves are controllable and configured to direct fluid flow into the plurality of adjustment inflatables. The assembly may also include a processor that receives data from the one or more sensors disposed on the housing and adjust one or more positions of the one or more valves based on the data to control fluid flow into one or more of the plurality of adjustment inflatables.

Abstract: A method may include acquiring, via a capture system, a dataset associated with a user at a first location, detecting, via a control system, the user at a second location, displaying, via an environmental system, one or more images generated from the dataset at the second location in response to detecting the user at or past the second location, and triggering, via a special effect system, a special effect during the displaying at the second location in response to detecting the user at or past the second location. The dataset may include image data of the user.

Abstract: Various examples and systems are provided for enhancing optical fibers for sensing temperature and/or strain at low temperatures (e.g., 1.8K to 77K or lower). An enhanced optical fiber for distributed sensing can comprise a core, a cladding surrounding the core, and a coating surrounding the cladding. A coefficient of thermal expansion (CTE) of the coating is greater than a CTE of silica and/or a Young's modulus (E) of the coating is greater than an E of silica.

Abstract: An augmented reality (AR) and 3-dimensional (3-D) viewing system for providing an AR and 3-D experience to a user includes a wearable visualization device having a viewing assembly through which the user is capable of viewing a real-world environment. The viewing assembly includes a first display configured to display one or more AR features and a 3-D viewing component that enables the user to perceive one or more coded 2-dimensional (2-D) images as one or more deciphered 3-D features. The AR and 3-D viewing system also includes a fixed 3-D display system having a second display configured to display the one or more coded 2-D images. The fixed 3-D display system is disposed within the real-world environment.

Abstract: Disclosed are various embodiments for a self-monitoring conducting device that responds to strain and temperature changes. In one example, a self-monitoring conducting device comprises a superconducting cable having a core and one or more layers of high-temperature superconductor (HTS) tape architecture surrounding the core. The self-monitoring conducting device further includes optical fibers integrated within the superconducting cable. The optical fibers can monitor a state of the superconducting cable along a length of the superconducting cable.

Abstract: Ferrite films, antennas including ferrite films, and methods of making thereof are provided. The methods can include tape casting of a slurry to produce a green film, wherein the slurry includes a ferrite powder, a dispersant, and a binder in a suitable solvent; and densifying the green film to produce the ferrite film having a thickness of 50 ?m to 5 mm. The methods can be used to make large area films, for example the films can have a lateral area of about 1000 cm2 to 3000 cm2. VHF/UHF antennas are including the ferrite films are also provided.

Abstract: A system may include a housing that may hold a body of water, an inflatable assembly disposed within the body of water, and a processor. The processor may receive an indication related to a speed of a flow of the body of water and send a signal to at least one valve coupled between the inflatable assembly and a fluid source in response to the indication. The signal may cause the at least one valve to fluidly couple the inflatable assembly to the fluid source to cause the inflatable assembly to expand to an inflated configuration.

Abstract: A hypersonic aircraft having a homopolar motor with high temperature superconducting (HTS) non-insulated (NI) coil magnets is described. In some implementations, the HTS NI coil magnets can have a graded resistance design. In some implementations, the HTS NI coil magnets can include a series of stacked coils, each of the series of coils comprising multiple turns having turn-to-turn resistance, where the turn-to-turn resistance of the series of coils is graded coil-to-coil across the magnet. In some implementations, the HTS NI coil magnets can include an NI coil comprising multiple turns and two or more thermal barriers each disposed between two adjacent turns of the coil, where an electrically conductive portion of one of the thermal barriers does not overlap with an electrically conductive portion of a different adjacent one of the thermal barriers. Some implementations can include a disk-type homopolar motor/generator including one or more HTS NI coil magnets.

Abstract: A system may include a housing that may hold a body of water, an inflatable assembly disposed within the body of water, and a processor. The processor may receive an indication related to a speed of a flow of the body of water and send a signal to at least one valve coupled between the inflatable assembly and a fluid source in response to the indication. The signal may cause the at least one valve to fluidly couple the inflatable assembly to the fluid source to cause the inflatable assembly to expand to an inflated configuration.

Abstract: A system may include a virtual reality system configured to present one or more virtual objects via an electronic display. The system may also include one or more inflatable objects that correspond to the one or more virtual objects, such that the one or more inflatable objects matches one or more shapes of the one or more virtual objects. The system may also include a processor configured to cause at least one of the one or more inflatable objects to inflate based on feedback from the virtual reality system.

Abstract: A system may include an inflatable assembly having a plurality of members. The system may also include a plurality of sensors disposed at a plurality of positions inside or around the inflatable assembly, such that the plurality of sensors may acquire data related to a shape of the inflatable assembly. The system also includes one or more valves, each configured to direct a fluid into a corresponding member of the plurality of members of the inflatable assembly. The system also includes a processor that adjusts positions of the one or more valves to cause the fluid to be directed into the corresponding member of the plurality of members of the inflatable assembly based on the data and a desired shape of the inflatable assembly.

Abstract: Disclosed are various embodiments for a self-monitoring conducting device that responds to strain and temperature changes. In one example, a self-monitoring conducting device comprises a superconducting cable having a core and one or more layers of high-temperature superconductor (HTS) tape architecture surrounding the core. The self-monitoring conducting device further includes optical fibers integrated within the superconducting cable. The optical fibers can monitor a state of the superconducting cable along a length of the superconducting cable.

Abstract: An inflatable assembly may include a housing that has a plurality of adjustment inflatables that may form a range of shapes at different levels of inflation. The inflatable may also include one or more sensors disposed on the housing and one or more valves disposed in the housing. The valves are controllable and configured to direct fluid flow into the plurality of adjustment inflatables. The assembly may also include a processor that receives data from the one or more sensors disposed on the housing and adjust one or more positions of the one or more valves based on the data to control fluid flow into one or more of the plurality of adjustment inflatables.

Abstract: A system may include an inflatable assembly having a plurality of members. The system may also include a plurality of sensors disposed at a plurality of positions inside or around the inflatable assembly, such that the plurality of sensors may acquire data related to a shape of the inflatable assembly. The system also includes one or more valves, each configured to direct a fluid into a corresponding member of the plurality of members of the inflatable assembly. The system also includes a processor that adjusts positions of the one or more valves to cause the fluid to be directed into the corresponding member of the plurality of members of the inflatable assembly based on the data and a desired shape of the inflatable assembly.

Abstract: A system may include a virtual reality system configured to present one or more virtual objects via an electronic display. The system may also include one or more inflatable objects that correspond to the one or more virtual objects, such that the one or more inflatable objects matches one or more shapes of the one or more virtual objects. The system may also include a processor configured to cause at least one of the one or more inflatable objects to inflate based on feedback from the virtual reality system.

Abstract: An inflatable assembly may include a housing that has a plurality of adjustment inflatables that may form a range of shapes at different levels of inflation. The inflatable may also include one or more sensors disposed on the housing and one or more valves disposed in the housing. The valves are controllable and configured to direct fluid flow into the plurality of adjustment inflatables. The assembly may also include a processor that receives data from the one or more sensors disposed on the housing and adjust one or more positions of the one or more valves based on the data to control fluid flow into one or more of the plurality of adjustment inflatables.

Abstract: A hypersonic aircraft having a homopolar motor with high temperature superconducting (HTS) non-insulated (NI) coil magnets is described. In some implementations, the HTS NI coil magnets can have a graded resistance design. In some implementations, the HTS NI coil magnets can include a series of stacked coils, each of the series of coils comprising multiple turns having turn-to-turn resistance, where the turn-to-turn resistance of the series of coils is graded coil-to-coil across the magnet. In some implementations, the HTS NI coil magnets can include an NI coil comprising multiple turns and two or more thermal barriers each disposed between two adjacent turns of the coil, where an electrically conductive portion of one of the thermal barriers does not overlap with an electrically conductive portion of a different adjacent one of the thermal barriers. Some implementations can include a disk-type homopolar motor/generator including one or more HTS NI coil magnets.