Methods, systems, and apparatus, including computer programs encoded on computer storage media, for initiating actions based on sequences of events. In one aspect, a process includes receiving, from each of multiple devices, data specifying an event detected by the device. The events are compared to configured scenarios that each specify a sequence of trigger events and an action to be initiated in response to detecting the sequence of trigger events. A determination is made that the events match a first scenario of the scenarios. In response to determining that the events detected by the multiple devices match the first scenario, a first action specified by the first scenario is initiated. A determination is made that a combination of one or more of the events detected by the multiple devices and the first action matches a second scenario. In response, a second action specified by the second scenario is initiated.

A cab having a human-machine interface to generate a holographic image in order to control comfort equipment installed in the cab. The human-machine interface includes: a camera capable of capturing images representing a gaze of an occupant, one image generation unit having (a) a computer capable of calculating the position of the location of the occupant's gaze from the captured images, the computer being adapted to generate the digital holographic image according to the position of the occupant's gaze, (b) a spatial light modulator receiving the generated digital holographic image, and (c) a light source illuminating the spatial light modulator. The human-machine interface also includes a reflector reflecting the light beams emitted by the spatial light modulator into a visualizing window to form a holographic image positioned between the windscreen and the seat.

A transparent pixel matrix, a screening layer, and a control circuit are included in a display apparatus. The control circuit displays a graphic object on the pixel matrix. The screening layer includes individually switchable segments arranged behind the pixel matrix and the segments are switchable with respect to their transparency between a minimum value and a maximum value. The control circuit selects the graphic object based on an input by the user. The control circuit signals the graphic object is selected by operating a first segment among the segments arranged behind the selected graphic object as a selection segment, with the minimum value of transparency or with the maximum value of transparency, and by operating a second segment among the segments as a background segment in a complementary fashion with respect to the selection segment, with the maximum value of transparency or the minimum value of transparency.

A vehicle and many dynamic features move relative to the same reference frame. An infotainment system responds to a request from an occupant of a vehicle to provide information concerning a particular dynamic feature. The occupant provides the infotainment system with information concerning a bearing to the dynamic feature and the infotainment system identifies the dynamic feature in response.

A vehicle part including a light source capable of emitting a light image, a micro-mirror plate capable of projecting the light image outside the vehicle part in the form of a hologram, a privacy filter located between the light source and the hologram, and a sensor capable of detecting the presence of any object in a projection plane coinciding at least partially with the hologram.

A cab having a human-machine interface to generate a holographic image in order to control comfort equipment installed in the cab. The human-machine interface includes: a camera capable of capturing images representing a gaze of an occupant, one image generation unit having (a) a computer capable of calculating the position of the location of the occupant's gaze from the captured images, the computer being adapted to generate the digital holographic image according to the position of the occupant's gaze, (b) a spatial light modulator receiving the generated digital holographic image, and (c) a light source illuminating the spatial light modulator. The human-machine interface also includes a reflector reflecting the light beams emitted by the spatial light modulator into a visualizing window to form a holographic image positioned between the windscreen and the seat.

The disclosure relates to a method for the contactless shifting of visual information, in which at least one viewing direction, a movement of a hand and/or a movement of a head of a user are detected. After the detection of the visual information in a first display area, and after a motion indicating a shift, the visual information is shown in the second display area upon the completion of the pivoting movement or movements.

A user interface, a computer program product, a signal sequence, a means of transportation and a method for classifying a user gesture performed freely in space. A first gesture and/or a second gesture may be detected by a sensor. A processor may compare a first characteristic of the first gesture with a first characteristic of a second gesture, and, as a function of the comparison, the first gesture may be classified in contrast to the second gesture as an intended user input.

Disclosed is a system for detecting command gestures made by a finger of a driver of a motor vehicle, including an interface pad, a light source that emits an optical beam in the infrared band toward the interface pad, an imaging sensor, for capturing images steered by the interface pad away from the driver, with a base frame and a movable plate, an optical zone of interest seen by the imaging sensor being defined at the interface between the base frame and the movable plate, the interface pad including an elastic deformable seal interposed between the base frame and the movable plate, the deformable seal including a first inclined facet, so that an optical path passing via the first inclined facet is proportionally modified by the deformation of the seal under the effect of the movement of the movable pad.

Systems and methods are provided for training a plurality of users of a vehicle to use gestures as a short-cut for controlling vehicle functions. The methods monitor a plurality of tasks related to controlling vehicle functions completed by a unique user. For each task, the method may determine whether the task has been completed by the unique user either using a predefined gesture associated with the task, or manually, without using the predefined gesture associated with the task. For each task, the method designates the predefined gesture as being either a learned gesture or an un-learned gesture. After a predetermined time period, the method may include determining that a gesture usage history associated with the unique user includes at least one un-learned gesture. User-customized instructions that at least one un-learned gesture is available for use as a short-cut for controlling a vehicle function may be presented to the unique user.