Abstract: There is disclosed devices, systems and methods for nonverbal multi-input and feedback devices for user intended computer control and communication of text, graphics and audio. The system comprises sensory devices comprising sensors to detect a user inputting gestures on sensor interfaces, a cloud system comprising a processor, for retrieving the inputted gestures detected by the sensor on the sensory device, comparing the inputted gestures to gestures stored in databases on the cloud system, identifying at least a text, graphics and/or speech command comprising a word that corresponds to the inputted gesture; showing the command to the user; and transmitting the command to another device.

Abstract: There is disclosed devices, systems and methods for nonverbal multi-input and feedback devices for user intended computer control and communication of text, graphics and audio. The system comprises sensory devices comprising sensors to detect a user inputting gestures on sensor interfaces, a cloud system comprising a processor, for retrieving the inputted gestures detected by the sensor on the sensory device, comparing the inputted gestures to gestures stored in databases on the cloud system, identifying at least a text, graphics and/or speech command comprising a word that corresponds to the inputted gesture; showing the command to the user; and transmitting the command to another device.

Abstract: A method and system of a user interface device with dual-sided display which may include a system using a brain computer interface with an Augmented Reality (AR) headset. The user's intent is sent to the system, which processes, analyzes and maps the user's intent. An output corresponding to the user's intent is projected using the user interface device. This output is displayed on the user's side of the display. An image corresponding to the output is displayed on the observer's side of the display.

Abstract: There is disclosed devices, systems and methods for nonverbal multi-input and feedback devices for user intended computer control and communication of text, graphics and audio. The system comprises sensory devices comprising sensors to detect a user inputting gestures on sensor interfaces, a cloud system comprising a processor, for retrieving the inputted gestures detected by the sensor on the sensory device, comparing the inputted gestures to gestures stored in databases on the cloud system, identifying at least a text, graphics and/or speech command comprising a word that corresponds to the inputted gesture; showing the command to the user; and transmitting the command to another device.

Abstract: An apparatus, system, and method of a brain computer interface in a headset including an augmented reality display, one or more sensors, a processing module, at least one biofeedback device, and a battery. The interface may include a printed circuit board that has the sensors to read bio-signals, provides biofeedback, and performs the processing, analyzing, and mapping of bio-signals into output. The output provides feedback via stimulation of multiple sensory brain systems of a user, including audio and visual on the augmented reality display, or audio and haptic in terms of vibration patterns that a human user may feel. All together this forms a closed-loop system, by detecting the bio-signal, then providing sensory-feedback, which in turn enhances the bio-signal.

Abstract: A method and system are disclosed using steady-state motion visual evoked potential stimuli in an augmented reality environment. Requested stimuli data are received from a user application on a smart device. Sensor data and other context data are also received, where other context data includes data that is un-sensed. The requested stimuli data are transformed into modified stimuli based on the sensor data, and the other context data. Modified stimuli and environmental stimuli are presented to the user with a rendering device configured to mix the modified stimuli and the environmental stimuli, thereby resulting in rendered stimuli. Biosignals generated in response to the rendered stimuli are received from the user to a wearable biosignal sensing device. Received biosignals are classified based on the modified stimuli, resulting in a classified selection, which is returned to the user application.