A method for generating navigation routes for a vehicle includes: receiving an origin position, in a road network, of the vehicle; receiving a destination position, in the road network; receiving a user preference from a user interface device, the user preference indicating a tradeoff value having one of a plurality of values between travel time and energy efficiency; computing a time value for each of a plurality of road segments of the road network using a time consumption model; computing an energy consumption for each of the plurality of road segments of the road network using an energy consumption model; identifying a weighted route from the origin position to the destination position based on the time value and the energy consumption for the road segments and based on the user preference; and supplying the identified weighted route to a navigation system of the vehicle.

In an apparatus for controlling driving of a vehicle, an input interface is configured to receive a reassurance indicator entered by a passenger of the vehicle. The reassurance indicator represents a preference of the passenger for security. A communication unit is configured to communicate with a plurality of roadside devices located in respective potentially risky areas where the vehicle may collide with a moving object. Each roadside device is configured to evaluate the collision possibility with the moving object. A vehicle controller is configured to, if receiving an evaluation result from the roadside device located in the potentially risky area forward of the own vehicle showing that the own vehicle is unlikely to collide with the moving object in the potentially risky area forward of the vehicle, perform avoidance control to control driving of the vehicle according to the reassurance indicator.

A system includes at least partially autonomous vehicles, at least partially separated interconnected roadways, and a management system. Each of the vehicles is configured to cooperate with another vehicle or an area controller. The management system is configured to receive requests to transport, which may have respective start points and respective destinations. Additionally, the management system is configured, responsive to receiving the request, to assign a vehicle to fulfill the request. The assigned vehicle is configured to transport a person from the respective start point, at least in part via the interconnected roadways, to the respective destination.

A system can receive a destination change request inputted by a passenger of an autonomous vehicle, where the destination change request comprises a request to change a first destination of the passenger to a second destination. In response to receiving the destination change request, the system determines a feasibility indicator for the autonomous vehicle to travel to the second destination, and based on the feasibility indicator, determines a suggested destination being different from the second destination. The system transmits an instruction to a computing system of the autonomous vehicle, causing the computing system of the autonomous vehicle to reroute the autonomous vehicle to the suggested destination. The system then transmits an instruction to a computing device associated with a non-autonomous vehicle, where the instruction comprises a request or invitation for a driver of the non-autonomous vehicle to transport the passenger from the suggested destination to the second destination.

A domestic destinator having an entry means is provided that is portable and may have a charging means, cable, wireless capabilities and or is an application suitable to run on computing devices and can include a monitor with a screen having a mounting accessory comprised of a base with a connecting means to a surface and a shaft. A domestic destinator capable of receiving destination entry to organize a list of locations in various visiting scenarios to display routing and navigation maps.

A map database stores data describing a set of connected roadways, each having one or more lanes. A coverage system selects lanes from the map database along which AVs can stop, such as parking lanes. The coverage system generates buffer regions for each of the stopping lanes, where each buffer region includes an area within a given distance of the respective lane. The coverage system combines the buffer regions to generate a coverage area, and provides a display of the coverage area overlayed over a map of roads corresponding to the coverage area.

A system includes at least partially autonomous vehicles, at least partially separated interconnected roadways, and a management system. Each of the vehicles is configured to cooperate with another vehicle or an area controller. The management system is configured to receive requests to transport, which may have respective start points and respective destinations. Additionally, the management system is configured, responsive to receiving the request, to assign a vehicle to fulfill the request. The assigned vehicle is configured to transport a person from the respective start point, at least in part via the interconnected roadways, to the respective destination.

A navigation system is described for a vehicle equipped with an autonomous driving system. The navigation system includes a human-machine interface with a display and a user control, and an electronic controller. The controller is configured to calculate a plurality of travel routes from a determined starting point to a defined destination point. The controller determines which portions of each travel route will utilized automated driving operation and which portions will utilized manual driving operation. Based on an input received from the user control, the controller defines an automatic-manual driving preference ratio indicating a driver preference for an amount of manual driving operation relative to an amount of automatic driving operation. The controller automatically selects a route from the plurality of travel routes that most closely matches the defined automatic-manual driving preference ratio and outputs the selected route on the display.

A method for planning a route in a system having a display and an input device, that comprises the steps of using a map database that stores data associated with an area that includes a required route; displaying the map or a portion thereof on the display, in this displaying step selecting the scale and position of the displayed map; adjusting and storing conditions or preferences as parameters associated with the required route; defining the requested route in which using said input device to draw the required route on the map displayed, storing the coordinate data of the required route; then determining a suggested route based on the required route, wherein an iteration algorithm is used to determine from successive points of the required route beginning with its starting point respective costs of vectors starting at said points and ending at points of possible routes that satisfy preset parameters and lie in the vicinity of said points of the required route, and selecting a suggested route from the plurality of said possible routes that has minimum overall cost, and storing and displaying this suggested route.

A method includes displaying information via a first display, displaying information via a second display, controlling the information displayed via the first display and the second display with a controller, and receiving a first input from a user through a user interface. The first input includes a command to change a setting of the first display or the second display and/or the information being displayed via the first display or the second display. The method also includes generating a first haptic effect to confirm receipt of the first input.