A system and method for an electric aircraft coaching simulator is illustrated. The simulator includes a pilot control that is configured to generate a pilot command. The simulator includes a processor that is configured to receive optimized flight data, simulate a battery performance of an electric aircraft as a function of the received pilot command and generate an optimal flight recommendation based off the optimized flight data. The simulation model is configured to communicatively connect with the flight simulator to mimic a real flight situation. Optimized flight data from other pilots can be used to coach pilots how to fly with more energy efficiency.

A system and method for an electric aircraft coaching simulator is illustrated. The simulator includes a pilot control that is configured to generate a pilot command. The simulator includes a processor that is configured to receive optimized flight data, simulate a battery performance of an electric aircraft as a function of the received pilot command and generate an optimal flight recommendation based off the optimized flight data. The simulation model is configured to communicatively connect with the flight simulator to mimic a real flight situation. Optimized flight data from other pilots can be used to coach pilots how to fly with more energy efficiency.

A flight simulation system for performing flight simulation of aircraft models includes a head-mounted display for displaying a virtual reality image of a cockpit including operational interfaces, a haptic device including a touch sensor for detecting a touch location touched by a user and a vibrator for causing a vibration, and a control device including a processor and a memory. The processor execute a process including: performing flight simulation of a model selected by the user; causing the head-mounted display to display the virtual reality image picturing the operational interfaces; when the user touches the haptic device, causing the vibrator to cause a vibration at the touch location; based on coordinate data indicating coordinate locations of the operational interfaces and the touch location, identifying an operational interface corresponding to the touch location; and applying a change based on an operation performed on the identified operational interface to flight simulation.

A flight simulation system for performing flight simulation of aircraft models includes a head-mounted display for displaying a virtual reality image of a cockpit including operational interfaces, a haptic device including a touch sensor for detecting a touch location touched by a user and a vibrator for causing a vibration, and a control device including a processor and a memory. The processor execute a process including: performing flight simulation of a model selected by the user; causing the head-mounted display to display the virtual reality image picturing the operational interfaces; when the user touches the haptic device, causing the vibrator to cause a vibration at the touch location; based on coordinate data indicating coordinate locations of the operational interfaces and the touch location, identifying an operational interface corresponding to the touch location; and applying a change based on an operation performed on the identified operational interface to flight simulation.

Method and system for visualizing dynamic virtual sub-systems of a virtual simulated element in an interactive computer simulation system comprising a computer generated environment. One or more tangible instruments control the virtual simulated element in the computer generated environment. A graphical user interface comprising an interactive display portion depicting a rendered view of the virtual simulated element. While an interactive computer simulation of the virtual simulated element is performed in the interactive computer simulation system, a storage system logs dynamic data in relation to the dynamic virtual sub-systems. At least one of the dynamic virtual sub-systems of the virtual simulated element is selected and a subset of dynamic data related to the selected virtual sub-system is loaded from the storage system. The selected virtual sub-system is displayed together with the related dynamic data on the graphical user interface.

Method and system for visualizing dynamic virtual sub-systems of a virtual simulated element in an interactive computer simulation system comprising a computer generated environment. One or more tangible instruments control the virtual simulated element in the computer generated environment. A graphical user interface comprising an interactive display portion depicting a rendered view of the virtual simulated element. While an interactive computer simulation of the virtual simulated element is performed in the interactive computer simulation system, a storage system logs dynamic data in relation to the dynamic virtual sub-systems. At least one of the dynamic virtual sub-systems of the virtual simulated element is selected and a subset of dynamic data related to the selected virtual sub-system is loaded from the storage system. The selected virtual sub-system is displayed together with the related dynamic data on the graphical user interface.

A system for flight control of a vertical take-off and landing (VTOL) aircraft includes a flight simulator communicatively coupled to a VTOL aircraft, wherein the flight simulator is configured to generate a model for at least a flight component and a flight controller, wherein the flight controller is configured to receive the model for the at least a flight component, determine a command for the at least a flight component as a function of the model, and initiate the command for the at least a flight component.

A system for flight control of a vertical take-off and landing (VTOL) aircraft includes a flight simulator communicatively coupled to a VTOL aircraft, wherein the flight simulator is configured to generate a model for at least a flight component and a flight controller, wherein the flight controller is configured to receive the model for the at least a flight component, determine a command for the at least a flight component as a function of the model, and initiate the command for the at least a flight component.

A system for flight simulation of an electric aircraft. The system includes a pilot control. The pilot control is configured to receive an input from a user. The system includes a pilot command that is generated by the pilot control. The system includes a computing device configured to generate a simulation. The simulation includes an electric aircraft model. The electric aircraft model is configured to simulate a performance of an electric aircraft. The performance is determined by at least the pilot command. The simulation is configured to provide feedback to the user based on the performance of the electric aircraft. The simulation is further configured to updated the electric aircraft model as a function of the pilot command.

A remote training apparatus for a drone flight in a mixed reality includes: a processor; and a memory, wherein the memory stores program instructions executable by the processor to generate a virtual flight space using arrangement information of one or more anchors and tags arranged in a physical space for the flight of the drone, and receive and register a flight training scenario generated in the virtual flight space from a second computer belonging to a remote expert group that remotely communicates with a first computer belonging to a drone operator group, wherein the flight training scenario includes one or more virtual obstacles and one or more flight instruction commands, and at least some of the flight instruction commands are mapped to the one or more virtual obstacles, and receive one or more annotations generated by the remote expert group from the second computer to transmit the annotations to the first computer.