A system includes a controller comprising at least one processor coupled to a memory storing instructions that, when executed by the at least one processor, cause the at least one processor to perform operations comprising: receiving information indicative of operation of the vehicle and of a driving condition for the vehicle; determining that a speed of the vehicle is less than a target speed for the vehicle based on the received information; determining, in response to the determination that the speed is less than the target speed, that the lane change and takeover event is at least one of feasible or efficient based on the received information; and providing, in response to the determination regarding the lane change and takeover event, a notification.

A system includes a controller comprising at least one processor coupled to a memory storing instructions that, when executed by the at least one processor, cause the at least one processor to perform operations comprising: receiving information indicative of operation of the vehicle and of a driving condition for the vehicle; determining that a speed of the vehicle is less than a target speed for the vehicle based on the received information; determining, in response to the determination that the speed is less than the target speed, that the lane change and takeover event is at least one of feasible or efficient based on the received information; and providing, in response to the determination regarding the lane change and takeover event, a notification.

Methods and systems are provided for detecting and responding to dangerous road users. In some aspects, a process can include steps for receiving sensor data of a detected object from an autonomous vehicle, determining whether the detected object is exhibiting a dangerous attribute, generating output data based on the determining of whether the detected object is exhibiting the dangerous attribute, and updating a machine learning model based on the output data relating to the dangerous attribute.

Methods and systems are provided for detecting and responding to dangerous road users. In some aspects, a process can include steps for receiving sensor data of a detected object from an autonomous vehicle, determining whether the detected object is exhibiting a dangerous attribute, generating output data based on the determining of whether the detected object is exhibiting the dangerous attribute, and updating a machine learning model based on the output data relating to the dangerous attribute.

A system for receiving user input from an internal vehicle component surface includes a flat surface layer of the internal vehicle component that includes a first portion made of an elastic material and a second portion that surrounds the first portion, and a push-button assembly located beneath the first portion of the flat surface layer. The push-button assembly includes a push-button switch that is switched into at least a first switching state by downward pressure, and a vertical movement mechanism that when activated causes the push-button switch to move vertically in a direction of the flat surface layer. Vertical movement of the push-button switch causes a vertical displacement of the first portion of the flat surface layer, and downward pressure on the first portion of the flat surface layer when vertically displaced causes a corresponding downward pressure to the push-button switch, switching the push-button switch into the first switch state.

A method for providing one or more of a rear or a side view of a vehicle includes generating a video stream of images subsequently captured by at least one camera of the vehicle or of a virtual mirror device of the vehicle, processing the generated video stream, and displaying the generated video stream on at least one screen of a display unit of the vehicle or of the virtual mirror device.

A method for providing one or more of a rear or a side view of a vehicle includes generating a video stream of images subsequently captured by at least one camera of the vehicle or of a virtual mirror device of the vehicle, processing the generated video stream, and displaying the generated video stream on at least one screen of a display unit of the vehicle or of the virtual mirror device.

A vehicle dashboard assembly includes a dashboard panel, a display support, a display and a display cover. The dashboard panel has a display receiving space. The display support is coupled to the dashboard panel. The display is removably and reinstallably attached to the display support. The display cover is movably coupled relative to the dashboard panel between a closed position and an open position. The display cover includes a first cover portion for covering a front side of the display and a second cover portion for covering one edge of the display. The first cover portion surrounds a screen of the display while in the closed position to define a display opening for viewing the screen. The first and second cover portions are movable as a unit between the closed and open positions.

A portable electronic device to be used as a keyless device of a vehicle includes a controlling circuit which includes a physiological feature detection module and a processing circuit. The physiological feature detection module is used for detecting a physiological feature of a person. The processing circuit is coupled to the physiological feature detection module and used for determining whether the person is an authorized user of the vehicle according to the detected physiological feature of the person, and for opening a car door of the vehicle or starting the vehicle when the person is identified by the processing circuit as the authorized user.

A baling system comprising a high capacity baler, and an electronic display configured to display baling information to an operator of the baling high capacity baler. The baler additionally comprises a first bale-forming area in which a first series of first individual bales can be formed, and a second bale-forming area in which a second series of second individual bales can be formed. The baler further comprises one or more first sensors configured to sense one or more parameters related to at least one of the first bales, and one or more second sensors configured to sense one or more parameters related to at least one of the second bales. The electronic display is configured to simultaneously display data generated from at least one of the first sensors and at least one of the second sensors.