A display system that is configured for integration into a vehicle comprises a light source and an optical subsystem optically coupled to the light source. The optical subsystem includes a reflector and at least one semi-reflective optic, wherein the optical subsystem is configured to direct light rays to provide a plurality of virtual images that appear to a viewer concurrently at a respective plurality of different optical depths, by causing light of each of the virtual images to travel a different distance within the optical subsystem before exiting the optical subsystem on a path toward eyes of the viewer.

Provided are a hybrid electric vehicle and driving mode control method and apparatus for the same. An engine start request is generated by a heating controller of the vehicle. A second time is determined on basis of a first time between the cancellation of a prevent engine start request and the generation of the engine start request. The engine is controlled so that the engine is further maintained in a started state during the second time after the engine start request is cancelled.

The present invention provides a work machine comprising an engine, an exhaust gas treatment device including a filter that catches particulate matter in exhaust gas discharged from the engine, and a display device that displays, when the filter is being regenerated through a rise in the temperature of the exhaust gas, the filter regeneration progress and a warning in association with the regeneration at the same time.

A driving characteristic determination device includes a hardware processor connected to a memory. The processor detects driving information indicating at least one of driving behavior for a vehicle by a driver, biological information of the driver during driving, and behavior of the vehicle. The processor calculates, on the basis of the driving information, numerical values indicating whether a cognitive function of the driver is high or low. The processor analyzes the numerical values indicating whether the cognitive function is high or low. The numerical values are analyzed as cognitive function characteristics relative to one or more different brain functions. The processor outputs information about an analysis result obtained by the analysis of the numerical values.

By a vehicle display system, a vehicle display method, a computer-readable non-transitory storage medium storing a vehicle display method, information is displayed on a first display screen of a first display and a second display screen of a second display in a cooperation manner. The first display and the second display are arranged vertically. A target person who visually recognizes the first display screen and the second display screen is selected. A display aspect of the information on the first display screen or the second display screen is changed.

A user interface system includes: an input device that receives an input of a user in a vehicle; a display that displays information in the vehicle; and a processor that determines whether to support a personal indication and a personal input for the user when receiving a request to enter personal information of the user, and supports to enter the personal information using the input device and the display as a result of the determination.

A display device included in a vehicle includes: a communication unit, a display; and a control unit. The communication unit can receive vehicle travel information. The processor can calculate a speed range based on the received vehicle driving information and control the display to display a graphic object representative of the calculated speed range on the display.

A vehicle includes receiving signals from a plurality of satellites; obtaining position information based on the received signal; detecting a driving speed and yaw rate; obtaining dead reckoning information based on position information about a position of a vehicle recognized in a previous cycle and the received detection information; predicting the position information based on the obtained dead reckoning information; obtaining a value of Euclidean distance based on the position information about the position of the vehicle recognized in the previous cycle and the obtained position information; generating a first outlier filter based on the value of the Euclidean distance; obtaining a value of Mahalanobis distance based on the obtained position information and the predicted position information; generating a second outlier filter based on the value of the Mahalanobis distance; recognizing a current position of the vehicle by fusing information passing through the first outlier filter and information passing through the second outlier filter; and outputting information about the current position of the recognized vehicle as an image or a sound.

A position in a left-right direction of a display position of a facility figure representing a facility is set to a position overlapping with a virtual line parallel to a traveling lane as viewed from a driver (c). A position in an up-down direction of the display position is determined to be a position overlapping with a road surface on the front side, the position separated upward by H1 from a lower end of a display area of a heads-up display when a distance L from a current position CP to a position TP of a facility is a distance ThL (b1), to be a position separated by H4 (H4<h1) when the distance L is zero, and such that distances H2 and H3 separated upward from the lower end of the display area gradually change from the distance H1 to the distance H4 as the distance L decreases from the distance ThL to zero (b2 and b3). The distance H1 is set such that the facility figure is displayed below a point facing the facility on the road surface on the front side when the distance L is the distance ThL.

Aspects of the present disclosure relate switching between autonomous and manual driving modes. In order to do so, the vehicle's computer may conduct a series of environmental, system, and driver checks to identify certain conditions. The computer may correct some of these conditions and also provide a driver with a checklist of tasks for completion. Once the tasks have been completed and the conditions are changed, the computer may allow the driver to switch from the manual to the autonomous driving mode. The computer may also make a determination, under certain conditions, that it would be detrimental to the driver's safety or comfort to make a switch from the autonomous driving mode to the manual driving mode.