A method for controlling vehicle operations based on user orientation and user interaction data is provided. The method includes detecting, using a sensor operating in conjunction with the computing device of the vehicle, an orientation of a part of a user relative to a location on a display that is positioned in an interior of the vehicle, detecting, using an additional sensor, an interaction between the user and a portion of the display positioned in the interior of the vehicle, determining, using the computing device, whether a distance between the location and the portion of the display satisfies a threshold, and controlling, by the computing device, an operation associated with the vehicle responsive to determining that the distance between the location and the portion of the display satisfies the threshold.

There is disclosed an electronic device including a communication circuitry, a processor, and a memory that stores instructions. The electronic device may be configured to acquire, from a plurality of external electronic devices that have received a wake-up utterance, state information indicating states of the plurality of external electronic devices, acquire control data corresponding to a control utterance subsequent to the wake-up utterance and instructing control of a first function, determine availability of the first function for at least one of the plurality of external electronic devices by using the state information, determine a target device to perform the first function from the plurality of external electronic devices, based on the availability, and control the target device so as to perform the first function.

A control device that sets a detection reference that serves as a reference according to which an electronic apparatus is operated based on a non-contact operation, includes: a detection unit that detects a position of an object that performs the non-contact operation; an acquisition unit that acquires information related to the object or information related to a user who performs the non-contact operation; and a control unit that performs control to operate the electronic apparatus and control to set the detection reference, based on the position of the object detected by the detection unit and the information acquired by the acquisition unit.

Wearable computing apparatuses, which can be adapted to be worn on a user's hand, are provided for augmented reality, virtual reality, and artificial intelligence interactions. Generally, the wearable computing apparatus can include a first subassembly comprising one or more processors, non-transitory memory for storing instructions, at least one haptic motor, and a first set of sensors configured to measure positional characteristics associated with a user's hand. The wearable computing apparatus can further comprise a second subassembly removably coupled to the first subassembly, the second subassembly including a plurality of leads each of which is attached to a finger and comprises a distal portion that houses a haptic motor and a second set of sensors. The second set of sensors is configured to measure positional characteristics associated with the user's fingers.

A system for controlling a vehicle display based on an occupant's gaze includes: a first occupant gaze recognition unit to recognize a gaze of a first occupant in a vehicle; a second occupant gaze recognition unit to recognize a gaze of a second occupant in the vehicle; an interest information display area crossover confirmation and priority determination unit to determine interest information from the gaze of the first occupant and the gaze of the second occupant, to confirm whether areas for displaying interest information on a windshield are mutually crossover with each other, and to determine a priority for display; and a display control unit to control a display in accordance with the priority for display.

An eyewear device with camera-based compensation that improves the user experience for user’s having partial blindness or complete blindness. The camera-based compensation determines features, such as objects, and then converts the determined objects to audio that is indicative of the objects and that is perceptible to the eyewear user. The camera-based compensation may use a region-based convolutional neural network (RCNN) to generate a feature map including text that is indicative of objects in images captured by a camera. The feature map is then processed through a speech to audio algorithm featuring a natural language processor to generate audio indicative of the objects in the processed images.

According to one embodiment, a method, computer system, and computer program product for network bandwidth conservation is provided. The embodiment may include monitoring eye focus of a user. The embodiment may include monitoring voice input of the user. In response to determining the eye focus of the user is on a video feed of another user for more than a threshold amount of focus time, the embodiment may include receiving the video feed of the another user. In response to determining the eye focus of the user is on a screen of a video conference and determining, based on the voice input, the user is speaking towards the screen of the video conference, the embodiment may include enabling a camera of the user and transmitting a video feed of the user.

A method for granting access to vehicle functionalities is provided. The method includes receiving a signal from a device that is external to the vehicle, the signal including identification data of an object associated with the device, comparing the identification data with user identifications stored in the memory of the vehicle, and granting, to the object, access to a first set of functionalities of the vehicle in response to determining that the identification data matches a first user identification of the user identifications stored in the memory of the vehicle.

Methods and apparatus provide for carrying out a method for rendering a virtual-three dimensional space on a display, including: acquiring information indicative of a position of a head mounted display worn on a head of a user; acquiring information indicative of a position of an input apparatus for use by the user; acquiring information indicative of an instruction entered in the input apparatus; and generating an image of the virtual three-dimensional space to be displayed on the head mounted display at a viewpoint position and a sightline direction, where the generating includes generating an image of the input apparatus at the position in the image determined on a basis of a relative position with the head mounted display of the input apparatus, and where the generating includes generating an image of a hand of the user when the user controls the input apparatus.

This invention is a non-invasive Brain to Computer Interface (BCI) method for interpreting a word, phrase, or command from brain activity by identifying a pattern of electromagnetic brain activity which occurs when a person uses different action modalities to communicate a word, phrase, or command. This method can enable people with neuromuscular limitations and/or paralysis to communicate. It can also enable people to communicate and/or to control environmental devices via their thought patterns in situations where communication via touch screen, keyboard, mouse, voice command, or gesture recognition is not appropriate and/or possible.