A display method includes obtaining image information, where the image information includes an eye of a first user, determining an eye position and a line-of-sight direction of the first user based on the image information, and adjusting a display manner of a first area in a display area based on the eye position and the line-of-sight direction of the first user. The display area is a display area of a head-up display or a display area of an augmented reality head-up display, and the first area includes privacy information of a second user.

Systems and methods for using image analysis techniques to facilitate adjustments to vehicle components are disclosed. According to aspects, a computing device may access and analyze image data depicting an individual(s) within a vehicle, and in particular determine a positioning of the individual(s) within the vehicle. Based on the positioning, the computing device may determine how to adjust a vehicle component(s) to its optimal configuration, and may facilitate adjustment of the vehicle component(s) accordingly.

A system includes a computer having a processor and a memory. The memory storing instructions executable by the processor to determine a presence of a passenger, determine an eye gaze direction of an operator based on an image of the operator, and determine a location of a hand of the operator based on the image of the operator. The system actuates a vehicle component based on the determined presence of the passenger, the determined eye gaze direction of the operator, and the determined location of the hand of the operator.

A light emission device is installed in a vehicle capable of changing a degree of involvement of a driver in surroundings monitoring during driving. A light emitter is configured to be located in a gaze stable field of view of the driver when an information display device is located in an effective field of view of the driver. The information display device is disposed on a side of a steering device in the mobile entity. The light emitter is configured to emit light in a manner according to the degree of involvement of the driver in the surroundings monitoring during driving.

A steering column assembly includes a steering wheel having a steering wheel rim, a steering wheel hub, and a rim extension segment. The steering column assembly also includes a motor operatively coupled to the rim extension segment. The steering column assembly further includes a jacket assembly operatively coupled to the steering wheel, wherein the jacket assembly defines a central passage extending in a longitudinal direction of the steering column assembly, wherein the central passage does not include a steering shaft therein.

A vehicle including a windshield, a flexible display screen, a flexible display screen attachment component, at least one processor, and at least one memory configured to store instructions is disclosed. The instructions, when executed by the at least one processor, cause the at least one processor to (i) generate a set of images from sensor data received from one or more sensors mounted on a body of the vehicle; and (ii) display the set of images on the flexible display screen attached to the flexible display screen attachment component while covering the windshield. The set of images has effects of adverse weather conditions or poor lighting conditions removed.

A user interface for controlling a function of a vehicle is provided. The user interface comprises a manual input device for generating a user input signal in response to manual actuation by a user and one or more proximity sensors for being arranged in a vicinity of the manual input device, wherein each proximity sensor is configured to generate a proximity sensor signal in response to presence of a hand in a vicinity of the proximity sensor. Furthermore, the user interface comprises a processing circuitry configured to control the function of the vehicle based on the user input signal and the one or more proximity sensor signals.

A cockpit display system includes a cockpit, a first display apparatus, a second display apparatus, a first light sensor, a second light sensor and a brightness distribution calculation module. The first light sensor is suitable for detecting a first ambient light brightness. The second light sensor is suitable for detecting a second ambient light brightness. The brightness distribution calculation module is suitable for respectively calculating a first brightness, a second brightness, a third brightness and a fourth brightness of the first display area and the second display area of the first display apparatus and the third display area and the fourth display area of the second display apparatus under a same display gray level according to the first ambient light brightness and the second ambient light brightness. The first brightness, the second brightness, the third brightness and the fourth brightness are different from each other.

A compact work machine, such as a compact track loader and/or a compact utility loader, which can carry and operate a wide range of attachments while maintaining a reduced operating footprint.

One example discloses a multi-display controller, including: a focus detector configured to detect an attention of a user; and one or more rendering engines configured to vary an attribute of at least one display in a set of two or more displays based the attention of the user.