A system for user interaction with an automated device includes a control system configured to operate the device during an operating mode corresponding to a first state in which the control system automatically controls the device operation, and the operating mode prescribes that a user monitor the device operation during automated control. The control system is configured to allocate a time period for the device to transition to a temporary state in which automated control is maintained and the user is permitted to stop monitoring and perform a task unrelated to device operation. The system includes a user interaction system including a visual display configured to present trajectory information, an indication as to whether an area is conducive to putting the device in the temporary state, and time period allocation information, the user interaction system including an interface engageable by the user to manage scheduling of allocated time period(s).

Provided are methods for operating a vehicle, which can include receiving, from one or more of at least one sensor placed within a vehicle or an application on a communication device connected to the vehicle, data indicative of at least one of an action or an appearance of a passenger of the vehicle; determining, based on the at least one of the action or the appearance, that a modification of at least one operational parameter of the vehicle is required; and modifying, in response to the determining, the at least one operational parameter of the vehicle. Systems and computer program products are also provided.

An automated driving system with assistance for a driver in performing a non-driving activity includes an assistance device configured to assist the driver in performing the non-driving activity. The automated driving system, in a first operating state controls the vehicle in an automated manner, and in a second operating state hands over control of the vehicle to the driver. The assistance device is configured to assist the driver in performing the non-driving activity if the automated driving system switches from the first operating state to the second operating state.

An HMI control device includes an automation level acquisition portion and a display control unit. The automation level acquisition portion acquires an autonomous driving level determined by a driving control device. The display control portion controls an image display operation of an HMI device according to the autonomous driving level acquired by the automation level acquisition portion. When terminating a high autonomous driving level as the autonomous driving level, the display control portion controls the HMI device to provide an action instruction display that instructs the driver to take a low-level associated state so as to handle a low autonomous driving level. The low autonomous driving level is the autonomous driving level under which an in-vehicle system including the driving control device is prohibited from performing at least one of a lateral motion control realized by performing steering and a longitudinal motion control realized by performing acceleration/deceleration.

The present disclosure relates to a touch sensor and a method for sensing a touch using the same, the touch sensor including a substrate, a first sensor and a plurality of second sensors provided on the substrate and configured to sense a location and a force of a touch, wherein the first sensor is disposed in a central area of one surface of the substrate, the plurality of second sensors are arranged to surround the first sensor, and a width of the plurality of second sensors increases as a distance from the central area increases.

A method for operating a navigation system for a motor vehicle with autopilot is disclosed, wherein the autopilot is designed to automatically carry out longitudinal and lateral guidance of the motor vehicle in the activated state during a piloted journey without assistance from a driver. The navigation system determines, for a destination prescribed by the user, a route to the destination on the basis of navigation data. The roads on which the activation of the autopilot is likely to be possible is determined using traffic data and on the basis of a predetermined activation condition for the autopilot.

An information processing device that is mountable on a vehicle, includes: an acquiring unit configured to acquire at least one of internal condition or external condition of a user of a digital content including a virtual space experience; an estimating unit configured to estimate a sickness status of the user based on the at least one of internal condition or external condition acquired by the acquiring unit; and a guidance processing unit configured to perform a guidance processing such that a driving state of the vehicle is guided to suppress sickness, depending on the sickness status of the user estimated by the estimating unit.

Aspects of the present disclosure relate to a control system, a system, a method, a vehicle and a non-transitory computer readable medium for receiving user movement data indicative of movement of a user's head; receiving object movement data indicative of movement of an object, the object being associated with a non-driving task; determining one or more relative movement parameters indicative of the relative movement of the user's head with respect to the object based at least in part on the received user movement data and the object movement data; and determining an attention level of the user to the non-driving task in based at least in part on the determined relative movement parameter.

The present disclosure relates to a touch sensor and a method for sensing a touch using the same, the touch sensor including a substrate, a first sensor and a plurality of second sensors provided on the substrate and configured to sense a location and a force of a touch, wherein the first sensor is disposed in a central area of one surface of the substrate, the plurality of second sensors are arranged to surround the first sensor, and a width of the plurality of second sensors increases as a distance from the central area increases.

A method for predicting and reducing kinetosis-induced disturbances of an occupant in driving of a vehicle includes detecting the occupant by a vehicle camera, determining a characteristic figure that indicates a probability of onset of kinetosis-induced disturbances as a function of stimuli acting on the occupant, an individual susceptibility of the occupant with respect to kinetosis, and a type of activity carried on while driving, and as a function of the determined characteristic figure determined, recommending at least one individual measure of a package of measures for preventing kinetosis-induced disturbances to the occupant or initiating automatically the at least one individual measure.