A method and device for controlling at least one force-feedback device associated with at least a part of the body of a user. As to control the user's experience of motion and movements induced by the displacement(s) of the force feedback device(s) following operations are performed: [a] determining a speed value of a movement of the at least a part of the body according to at least a parameter representative of the displacement of the at least one force-feedback device, the movement of the at least a part of the body being induced by the displacement of the at least one force-feedback device; [b] comparing the determined speed value with a threshold speed value as to determine whether the displacement of the at least one force-feedback device is perceived by the user; and [c] controlling the at least one parameter according to the comparison result.

Some implementations include a method for operating a centrifuge-based-flight simulator in at least one of several different modes: a heightened G-force mode, a normal G-force mode; and transition modes (i.e., ramp-up or ramp-down modes) between the heightened G-force and normal G-force modes. During the normal-G-force mode the simulator ceases planetary motion altogether or substantially decreases rotations to replicate a plurality of flight conditions that physically imparts, on the trainee during operation of the simulator, a G-force that is not greater than approximately one (1) G. The reduction of planetary motion while maintaining realistic motion and force sensations that are appropriate for the virtual-flight conditions being experienced allows realistic flight simulation experience for the trainee and reduces the negative effects of constant planetary motion.

Some implementations include a method for operating a centrifuge-based-flight simulator in at least one of several different modes: a heightened G-force mode, a normal G-force mode; and transition modes (i.e., ramp-up or ramp-down modes) between the heightened G-force and normal G-force modes. During the normal-G-force mode the simulator ceases planetary motion altogether or substantially decreases rotations to replicate a plurality of flight conditions that physically imparts, on the trainee during operation of the simulator, a G-force that is not greater than approximately one (1) G. The reduction of planetary motion while maintaining realistic motion and force sensations that are appropriate for the virtual-flight conditions being experienced allows realistic flight simulation experience for the trainee and reduces the negative effects of constant planetary motion.

A simulated payload apparatus (SPA) for testing in a flight motion system (FMS), which has a body for mounting in the FMS, and which simulates an actual payload during the FMS test. The SPA may include a plurality of adjustable weights that are mountable on and/or removable from the body to vary the mass and/or center of gravity of the SPA. The SPA may include an adjustable bracket for interfacing with a motion drive of the FMS, in which the bracket is positionable along the body to vary the moment of inertia of the SPA. The SPA may include an onboard electronic measurement device that is configured to measure a motion characteristic of the SPA and/or communicate information about the measured motion characteristic in real-time during the FMS test. The SPA may include a laser alignment for aligning the SPA relative to test equipment of the FMS.

A method is described. The method comprises obtaining a recording of one or more physical interactions performed in relation to one or more physical components, in a simulation environment, playing back the recording such that the one or more physical interactions are represented in the simulation environment, and in the simulation environment, detecting a user interaction with one or more physical components of the simulation environment. The method further comprises determining whether the user interaction is congruent with at least one corresponding physical interaction of the one or more physical interactions in the recording, and in response to such congruence, continuing playback of the recording in the simulation environment.

Systems and methods are disclosed for virtual reality (VR) aircraft test and training environments that simultaneously leverage a high quality immersive environment engine and an operational flight program (OFP) running on a virtual flight management computer (FMC) by using a communication channels that couples the immersive VR environment engine with the virtual FMC. Existing investment in flight simulators, test environment core components, and any of navigation simulation, data link simulation, air traffic control simulation, and flight visualization modules can be advantageously employed to provide high-quality, realistic testing and training capability.

Systems and methods are disclosed for virtual reality (VR) aircraft test and training environments that simultaneously leverage a high quality immersive environment engine and an operational flight program (OFP) running on a virtual flight management computer (FMC) by using a communication channels that couples the immersive VR environment engine with the virtual FMC. Existing investment in flight simulators, test environment core components, and any of navigation simulation, data link simulation, air traffic control simulation, and flight visualization modules can be advantageously employed to provide high-quality, realistic testing and training capability.

A transducer switch includes a housing, a pushbutton switch near the rear of the housing, an input shaft extending from the front of the housing such that an input force can be applied to the input shaft, a positioning spring adapted and configured to resist movement of the input shaft and bias the input shaft towards alignment with the central axis, and a plurality of strain gauges positioned on a sensing portion of the input shaft. The plurality of strain gauges are adapted and configured to measure tension and compression on at least two sides of the input shaft, the two sides separated by approximately ninety degrees.

A simulated payload apparatus (SPA) for testing in a flight motion system (FMS), which has a body for mounting in the FMS, and which simulates an actual payload during the FMS test. The SPA may include a plurality of adjustable weights that are mountable on and/or removable from the body to vary the mass and/or center of gravity of the SPA. The SPA may include an adjustable bracket for interfacing with a motion drive of the FMS, in which the bracket is positionable along the body to vary the moment of inertia of the SPA. The SPA may include an onboard electronic measurement device that is configured to measure a motion characteristic of the SPA and/or communicate information about the measured motion characteristic in real-time during the FMS test. The SPA may include a laser alignment for aligning the SPA relative to test equipment of the FMS.

A portable cockpit seat apparatus, the apparatus including a portable cockpit seat, wherein the portable cockpit seat includes a hinge and has a stowed position, wherein the portable cockpit seat is folded about the hinge. The apparatus further including a headset including a display, and at least a flight control communicatively connected to the headset. The headset configured to and display a cockpit view of an aircraft. The flight control of the at least a flight control is connected to the portable cockpit seat and the at least a flight control, in response to actuation by a user, is configured to send a thrust signal, wherein the thrust signal causes the aircraft to alter its thrust and send a lift signal, wherein the lift signal causes the aircraft to alter its lift.