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.

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.

Method and system for dynamically modifying, in an interactive computer simulation station, visual rendering of a visual element in a computer generated environment from an interactive computer simulation. Pre-defined visual characteristics comprise a visual contouring associated with the visual element. The method comprises receiving, via a tangible instrument module, one or more commands for controlling a simulated vehicle. The method also comprises dynamically affecting the visual contouring of the visual element considering at least one of a distance factor between the simulated vehicle and the visual element in the computer generated environment and a relative contrast between the pre-defined visual characteristics of the visual element and underlying computer generated environment elements. The distance factor and the relative contrast are determined in real-time during execution of the interactive computer simulation prior to rendering the visual element for display.

A multi-view display device includes a display screen component and an optical structure component. The display screen component includes a plurality of pixels, and each of the plurality of pixels includes a left sub-pixel and a right sub-pixel. The optical structure component is disposed at the display screen component. When light beams from the left sub-pixel and light beams from the right sub-pixel of the each of the plurality of pixels pass through the optical structure component, the optical structure component separates the light beams from the left sub-pixel and the light beams from the right sub-pixel so as to generate correspondingly a left image and a right image to reach the first pilot position and the second pilot position, respectively. In addition, a manipulation simulation device is also provided.

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.

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.

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.

Method and system for dynamically modifying visual rendering of a visual element in a computer generated environment from an interactive computer simulation. Pre-identified distinctive visual characteristics are associated with the visual element. A tangible instrument module is sued to provide one or more commands for controlling a simulated vehicle of the interactive computer simulation. At the interactive computer simulation station, dynamically modifying the one or more pre-identified distinctive visual characteristics of the visual element is performed considering at least a relative directional vector between the simulated vehicle and the visual element in the computer generated environment, the relative directional vector being determined in real-time during execution of the interactive computer simulation prior to rendering the visual element for display.

Method and system for dynamically modifying, in an interactive computer simulation station, visual rendering of a visual element in a computer generated environment from an interactive computer simulation. Pre-defined visual characteristics comprise a visual contouring associated with the visual element. The method comprises receiving, via a tangible instrument module, one or more commands for controlling a simulated vehicle. The method also comprises dynamically affecting the visual contouring of the visual element considering at least one of a distance factor between the simulated vehicle and the visual element in the computer generated environment and a relative contrast between the pre-defined visual characteristics of the visual element and underlying computer generated environment elements. The distance factor and the relative contrast are determined in real-time during execution of the interactive computer simulation prior to rendering the visual element for display.

The present disclosure describes systems and methods for training a user to control one or more simulated remotely operated machines. A network stream definition language file is used to identify and process simulated remotely operated machine data exchanged between a simulation computing device and a plurality of simulation stations, possibly being defined by many different Interface Control Documents (ICDs). Any exchange of simulated remotely operated machine data between the simulation computing device and a simulation station passes through a protocol gateway that implements the network stream definition language file. The protocol gateway is located at any point of the communication between the simulation computing device and the simulation station. Because the network stream definition language file configures the protocol gateway to process data between the simulation computing device and the plurality of simulation stations, each potentially having respective proprietary ICDs, only a single protocol gateway is necessary within the system.