A trainable transceiver is provided for a vehicle for transmitting signals to a device remote from the vehicle. The trainable transceiver includes an RF transceiver configured to receive an RF signal during a training mode in order to learn characteristics of the received RF signal, and to transmit an RF signal to the remote device in an operating mode where the transmitted RF signal includes the learned characteristics of the received RF signal; a local memory device for storing channel data representing the learned characteristics of the received RF signal; an interface configured to communicate with an Internet-connected device; and a controller coupled to the local memory device and the interface, the controller configured to retrieve the channel data from the local memory device and transfer the channel data for storage remote from the vehicle using the interface. The controller may also receive channel data from the remote memory device.

Methods and systems are provided for providing training on a vehicle. The method includes acquiring, using processing circuitry, one or more alert modes associated with a vehicle. Further, the method includes controlling one or more alert devices as a function of a first alert mode. The first alert mode is selected from the one or more alert modes. The method includes outputting information to a user associated with the first alert mode via one or more output devices.

Methods and systems are provided for providing training on a vehicle. The method includes acquiring, using processing circuitry, one or more alert modes associated with a vehicle. Further, the method includes controlling one or more alert devices as a function of a first alert mode. The first alert mode is selected from the one or more alert modes. The method includes outputting information to a user associated with the first alert mode via one or more output devices.

A simulation device includes an outer frame and an inner frame. The outer frame is fixed to a floor surface and the inner frame is slideably interfaced to the outer frame. The inner frame has an inner frame axis. A hydraulic cylinder is interfaced between the outer frame and the inner frame. Operation of the hydraulic cylinder slides the inner frame with respect to the outer frame along the inner frame axis. A yaw platform is interfaced to the inner frame at one end at a pivot and at a distal opposing end by two or more bearings. The yaw platform has a yaw platform axis. Operation of a yaw motor or a yaw hydraulic ram interfaced between the yaw platform and the inner frame causes the yaw platform to change an angle between the inner frame axis and the yaw platform axis, providing simulation of yaw (loss of control).

A simulation device includes an outer frame and an inner frame. The outer frame is fixed to a floor surface and the inner frame is slideably interfaced to the outer frame. The inner frame has an inner frame axis. A hydraulic cylinder is interfaced between the outer frame and the inner frame. Operation of the hydraulic cylinder slides the inner frame with respect to the outer frame along the inner frame axis. A yaw platform is interfaced to the inner frame at one end at a pivot and at a distal opposing end by two or more bearings. The yaw platform has a yaw platform axis. Operation of a yaw motor or a yaw hydraulic ram interfaced between the yaw platform and the inner frame causes the yaw platform to change an angle between the inner frame axis and the yaw platform axis, providing simulation of yaw (loss of control).

An application for an adaptive training system includes a computer interfaced to one or more graphics displays, one of more input/output devices and having access to a plurality of training segments. The input/output devices are in communication with a trainee. Software operates in either a simulation mode in which a trainee interacts with the adaptive training system as if the trainee was operating a target vehicle or in a training mode in which the trainee receives computer-based training from the adaptive training system, in particular, when the trainee does not perform well during the simulation mode of operation.

An application for an adaptive training system includes a computer interfaced to one or more graphics displays, one of more input/output devices and having access to a plurality of training segments. The input/output devices are in communication with a trainee. Software operates in either a simulation mode in which a trainee interacts with the adaptive training system as if the trainee was operating a target vehicle or in a training mode in which the trainee receives computer-based training from the adaptive training system, in particular, when the trainee does not perform well during the simulation mode of operation.

A motion simulator for imposing loads on an occupant, the simulator having: a movable carrier for supporting the occupant; a first drive mechanism for moving the carrier; multiple loading elements configured for attachment to the occupant when the occupant is supported by the carrier; a second drive mechanism for actuating the loading elements to apply loads to the occupant; and a controller, the controller being configured to implement a simulation of a motion event by: (i) estimating a motion of the carrier consistent with the motion event and controlling the first drive mechanism to cause the carrier to adopt the estimated motion; (ii) estimating a first load on the occupant consistent with the motion event; (iii) estimating a second load on the occupant due to the motion adopted by the carrier and (iv) controlling the second drive mechanism to cause the second drive mechanism to apply to the occupant a load that is the difference between the first estimated load and the second estimated load.

A motion simulator for imposing loads on an occupant, the simulator having: a movable carrier for supporting the occupant; a first drive mechanism for moving the carrier; multiple loading elements configured for attachment to the occupant when the occupant is supported by the carrier; a second drive mechanism for actuating the loading elements to apply loads to the occupant; and a controller, the controller being configured to implement a simulation of a motion event by: (i) estimating a motion of the carrier consistent with the motion event and controlling the first drive mechanism to cause the carrier to adopt the estimated motion; (ii) estimating a first load on the occupant consistent with the motion event; (iii) estimating a second load on the occupant due to the motion adopted by the carrier and (iv) controlling the second drive mechanism to cause the second drive mechanism to apply to the occupant a load that is the difference between the first estimated load and the second estimated load.

A large projection image screen device having a seesaw structure for virtual reality where a chair is provided on one side of a lever and an image system is provided on the other side of the lever. Several rotation shafts are provided below the lever for up down rotation, left right rotation and front rear rotation, where when the chair and the screen are rotated up and downward, left and rightward, and front and rearward, a user on the chair views the images at the same view angle as the rotation angle of the screen through a location tracing device.