Various aspects of a device and method to manage interaction with one or more control circuits in a vehicle and one or more wearable devices are disclosed herein. The device comprises one or more circuits configured to receive a first set of input values from the one or more wearable devices associated with a first user. The one or more wearable devices are communicatively coupled to the device used in the vehicle. A second set of input values is received from one or more vehicle sensors embedded in the vehicle. An operating mode of the device is determined based on the received first set of input values and the second set of input values. One or more functions of the vehicle are controlled based on the determined operating mode of the device.

A vehicle notification apparatus is equipped to a subject vehicle having a notification portion for providing a notification to an occupant, and outputs, to the notification portion, a notification signal for providing the notification about a non-subject vehicle. The vehicle notification apparatus includes a determination portion determining whether the subject vehicle is travelling on a road where a lane change is allowed, and a notification determination portion determining whether to output the notification signal to the notification portion according to a distance between the subject vehicle and the non-subject vehicle and a relative speed of the non-subject vehicle with respect to the subject vehicle when the determination portion determines that the subject vehicle is travelling on the road where the lane change is allowed.

For the operation of a motor vehicle, according to the present disclosure, situation variables are detected using a number of environment sensors, a current driving situation is derived from the number of situation variables using a controller and a number of control inputs used to control the motor vehicle are detected, and a behavior pattern for a specific driver is determined using the controller on the basis of the control inputs, is assigned to the current driving situation, and is stored in a memory unit of the controller. Should it be concluded on the basis of the situation variables that the view is limited, the lack of certainty of the behavior pattern determined for the current driving situation is compared with that of a behavior pattern for the same driver determined for a driving situation with an unrestricted view, and the use of a system to improve the view is recommended to the driver if a lack of certainty on the part of the driver is identified on the basis of the comparison.

A transport safety system (400) for use in airports comprising a status monitor (300) for an airside dolly (200) used to improve airport safety. The status monitor (300) comprises a sensor (303) configured to sense a safety variable of the airside dolly and an output (301) in communication with the sensor (303). The output (303) is configured to provide a status signal in dependence on the sensed safety variable of the airside dolly (200).

A system for enhancing the visibility of a ground surface adjacent to a land vehicle is provided. The system includes a mobile communication device, a hand-held communication device and control logic coupled to the mobile device and operative to determine if the hand-held device is an authorized device. An imaging assembly is supported on the vehicle to obtain an image of the ground surface. An image processor processes the image to detect an obstacle located on the ground surface. The control logic is operative to generate a display command signal. A display device is responsive to the signal to display in real time the detected obstacle or a welcome mat onto or adjacent the vehicle for enhanced viewing by an approaching pedestrian when the pedestrian carrying the authorized device is located within a predetermined range of the mobile device.

Proposed is a method for controlling a vehicle through a multi System on Chip (SoC) system. Specifically, proposed is a method for controlling a vehicle, the method comprising the steps of: by means of a first SoC, requesting information to a second SoC or an Adaptive Driver Assistant System (ADAS); by means of the first SoC, receiving the information from the second SoC or the ADAS as a response to the request; by means of the first SoC, determining whether a vehicle is safe or not by using the received information; and by means of the first SoC, transmitting a command generated on the basis of the determination to the second SoC or the ADAS.

Systems and methods for smoothing automated lane change (ALC) operations. A mission planner, upon receipt of an ALC request, sends a ALC heads up signal to a lateral control. The mission planner then begins confidence building operations, for a preprogrammed duration of time, and awaits an ALC ready signal from the lateral control. The lateral control, upon receipt of the ALC heads up, calculates an index of readiness, R.sub.ALC, as a function of the requested ALC, a current trajectory, and a lane centering control path. When R.sub.ALC is less than or equal to a readiness threshold, Rt, the lateral control sends the ALC ready signal. When R.sub.ALC is greater than Rt, the lateral control generates a steering correction and applies the steering correction to reduce the R.sub.ALC and thereby stabilize the vehicle and send the ALC ready signal. Upon receiving the ALC ready signal, the ALC operation is executed.

A vehicle system includes: a steering device including an operation member, a turning member mechanically separated from the operation member and configured to turn a wheel, a reaction force actuator configured to apply a reaction force to the operation member, and a turning actuator configured to drive the turning member; a controller; and a display device. The controller is configured to determine whether a steering angle of the operation member and a turning angle of the wheel are in a phase deviation state, and cause the display device to perform a guidance display and an actual state display in a case where the steering angle and the turning angle are in the phase deviation state, the guidance display prompting a driver to perform an operation for phase matching to improve the phase deviation state, the actual state display indicating an actual turning state of the wheel.

An example method includes detecting a potential threat to a vehicle that is external to the vehicle, determining a severity level of the potential threat and a location of the potential threat relative to the vehicle, and displaying an indication of the potential threat on an electronic display in a particular portion of the electronic display corresponding to the location and with a particular display attribute corresponding to the severity level. The particular portion is one of a plurality of different portions of the electronic display each corresponding to different threat locations, and the particular display attribute is one of a plurality of different display attributes corresponding to different severity levels. A corresponding system that detects and displays notifications of potential threats is also disclosed.

A stop range indication device and a stop range indication method for a vehicle are proposed. The device and the method calculate an estimated stop range of a host vehicle using a variety of pieces of information during deceleration traveling of the host vehicle and provide visual guidance to a driver by displaying a stop range ahead of the host vehicle in accordance to the result of the calculation, thereby enabling the driver to drive safely while recognizing the stop range ahead of the host vehicle.