A compass device includes a base seat, a vial unit received in an accommodation hole of the base seat, an azimuth unit rotatably sleeved around the vial unit, a first spring wire disposed to resiliently retain the vial unit to the azimuth unit for magnetic declination adjustment, and a second spring wire disposed to resiliently retain the azimuth unit to the base seat for bearing angle measurement.

A work vehicle guidance display system comprising: at least one imaging device disposed on a work vehicle; a display disposed in the work vehicle configured to display images from the imaging device; and a controller configured to: select a field of view of the imaging device to display; receive a static dimension associated with the work vehicle; receive a dynamic dimension associated with the work vehicle; and display on the display a field view with a first machine travel path based on the static dimension and a second machine travel path based on the dynamic dimension.

A robot according to an embodiment of the present disclosure includes an authentication interface for authenticating a user's boarding of the robot using authentication information of the user, a position detector for detecting a position of the robot in a space, a processor for identifying a first section corresponding to the detected position among at least one section in the space, recognizing at least one driving mode for the first section among a plurality of driving modes with different driving speeds, setting one of the recognized at least one driving mode as a driving mode for the first section based on the authentication information, and controlling driving of the robot based on the set driving mode, and a display for outputting information on the set driving mode.

An antenna installation configuration includes: a vehicle-mounted apparatus that is mounted to a dashboard of a vehicle, the vehicle-mounted apparatus including a human-machine interface and a main body that is arranged in front of the human-machine interface, relative to a traveling direction of the vehicle; and an antenna attached to the main body, the antenna having a directivity directed toward an inside of a cabin of the vehicle and bypassing the human-machine interface.

An interface device connects to a mobile application running on a mobile device to provide vehicle navigation assistance. The interface device includes a microphone, a location determining component, a display, a plurality of indicator lights, a short-range communications transceiver, and a controller. The controller is configured to: receive a spoken instruction or query from a user via the microphone; send data associated with the spoken instruction or query to the mobile application running on the mobile device via the short-range communications transceiver; receive navigation data based on the spoken instruction or query from the mobile application running on the mobile device via the short-range communications transceiver; determine a current position based on one or more signals received via the location determining component; and provide at least one of a symbolic output or a textual output via the display based on the navigation data and the current position.

The functionality of two gauges is provided in the dashboard space required by one gauge by an articulating transparent display, which is attached to another, in-dash gauge using a hinge.

A system and method to transport one or more persons or objects. The system includes pods that each have an interior space to house the one or more persons or objects, and vehicles that are each configured to individually connect to one or more of the pods and to transport the pods from a first location to a second location. A server is located remotely from the pods and the vehicles. The server is configured to receive data from the pods and the vehicles through a wireless communication network to monitor a usage and location of the pods.

Methods and systems for a complete vehicle ecosystem are provided. Specifically, systems that when taken alone, or together, provide an individual or group of individuals with an intuitive and comfortable vehicular environment. The present disclosure includes a universal chassis that may be mounted in the head unit of a vehicle. The chassis may accept one or more modules that each have common dimensions. With a common form factor, the universal chassis is configurable as different modules with different functionality may be inserted into the chassis with ease.

An in-vehicle information display apparatus and a method of controlling the same output outputting various pieces of information using image output devices disposed on a rear surface of a protrusion type information display apparatus. The protrusion type information display apparatus applied to a vehicle includes an output region determination unit configured to, upon detecting that an event occurs, determine an image corresponding to the event and an output region, among a plurality of regions of a windshield, a screen correction unit configured to correct the determined image to match the determined output region, and a projector unit disposed on a rear surface opposite to a front surface on which a display is disposed and configured to project the corrected image onto the determined output region.

A vehicle communication system includes a first on-board device a first on-board device installed in a vehicle and a first communication device configured to be connected to the first on-board device. Individual identification information used to identify the first communication device as an individual communication terminal is added to the first communication device. The first communication device is configured to transmit the individual identification information to the first on-board device. The first on-board device is configured to associate vehicle information of the vehicle with the individual identification information and transmit the vehicle information associated with the individual identification information to an information device via the first communication device.