A virtual image display device includes a virtual image position selector, a vision measurement interface, a display information acquirer, a display image generator, and a projection processor. The virtual image position selector selects either a first virtual image position or a second virtual image position as a display position of the virtual image. The vision measurement interface measures a vision of a user based on a user's response to a vision measurement image projected as a virtual image at the display position. The display information acquirer acquires information to be shown. The display image generator generates a display image showing an image corresponding to the information acquired by the display information acquirer in a size determined by the vision acquired by the vision measurement interface. The projection processor performs a projection process of projecting the display image generated by the display image generator as a virtual image.

A non-contact operating apparatus, for a vehicle, includes a generating unit, a projecting device, a detecting device, and a setting unit. The generating unit is configured to generate and update an image containing an image object. The image object is operable by an occupant present within a vehicle compartment of the vehicle. The projecting device is configured to project the image in a predetermined display region within the vehicle compartment of the vehicle. The detecting device is configured to detect a riding state of the occupant who is present in the vehicle compartment of the vehicle. The setting unit is configured to instruct the projecting device or the generating unit to project the image at a position at which the image object is operable by the occupant who is in the riding state detected by the detecting device.

A control apparatus for providing a user interface to a user is provided. The apparatus comprises a display control unit configured to display a selectable object on a display apparatus, a detection unit configured to analyze an image of a hand of the user to detect a position of the hand, a specifying unit configured to specify an indicated position in the display apparatus based on the position of the hand, and a processing unit configured to, based on the indicated position overlapping the selectable object, execute processing associated with the selectable object. The display control unit further displays, in the display apparatus, a cursor that indicates the indicated position.

This disclosure provides an in-vehicle mid-air gesture-based interaction method, an electronic apparatus, and a system, and relates to the field of intelligent vehicle technologies. The method includes: obtaining a first mid-air gesture detected by a camera; and starting, when a preset response operation corresponding to the first mid-air gesture matches a first user who initiates the first mid-air gesture, the preset response operation corresponding to the first mid-air gesture in response to the first mid-air gesture. The method can be used in an in-vehicle mid-air gesture-based interaction scenario, reduce a mid-air gesture operation rate, and improve driving safety and interaction experience.

Embodiments generally relate to a system and a machine-readable medium for providing an entrainment experience to a user. The system comprising an experience system in communication with one or more human sensory inputs and an entraining rhythm generation unit. The experience system configured to receive entraining rhythm information from the entraining rhythm generation unit, determine the entrainment experience based on the entraining rhythm information, and provide the entrainment experience to the user via the one or more human sensory inputs.

A vision sensor system is used for gesture recognition or another control system with a human-machine interface. In the vision sensor system, a vision sensor 1 is used in particular to check the presence, the orientation, the characteristics or the texture of an object 15. For this purpose, the vision sensor 1 has a housing 2 in which a light-receiving element 3 is arranged. At a distance from the light-receiving element 3 there is a cover made of a translucent carrier material 5 with a first surface 6 facing the light-receiving element 3 and a second surface 7 facing away from the light-receiving element 3, both located in the beam path 4 of the light-receiving element 3. The carrier material 5 has at least partially a translucent metallic coating 8, 9 on at least one of the first or second surfaces 6, 7 located in the beam path 4 of the light receiving element 3.

Disclosed is a cabin system configured to acquire first information about a first user and second information about a second user through a communication device, to specify each of the first user and the second user based on image data received from an internal camera or an external camera, to provide a control signal to a display or a speaker such that content is provided to a user based on an electrical signal generated by an input device, to determine a first boarding seat of the first user among seats according to the first information and to determine a second boarding seat of the second user among the seats according to the second information, and to determine the posture of the first boarding seat according to the first information and to determine the posture of the second boarding seat according to the second information.

An electronic device mountable in a car includes a first sensor configured to detect a gesture that does not come into contact with the electronic device, a second sensor configured to detect a touch that comes into contact with the electronic device, and a controller. The controller is configured to reduce the size of icons, displayed on a display, when detection by the first sensor is enabled and the car is moving.

An example operation includes one or more of receiving, by a computer associated with a transport, a gait of an individual from at least one camera associated with the transport, validating, by the computer, the gait, receiving, by the computer, a gesture of the individual from the at least one camera, validating, by the computer, the gesture, and performing, by the computer, one or more functions based on the validated gait and the validated gesture.

An onboard equipment operating device includes a memory, a processor, a display unit, an operation unit, and an in-cabin camera. The display unit displays information regarding onboard equipment, instruction to the onboard equipment displayed at the display unit is configured to be received as a result of manual operation of the operation unit. The in-cabin camera captures images of a vehicle occupant. The processor is configured to: detect a predetermined action from actions of a face or a body of the vehicle occupant, the actions of the face or the body of the vehicle occupant being imaged by the in-cabin camera; input an instruction corresponding to the predetermined action to the onboard equipment; and display the information regarding the onboard equipment in an operatable state at the display unit, in a case in which the instruction corresponding to the predetermined action has been input to the onboard equipment.