An interactive autonomous driving system for an autonomous driving vehicle may include: a target mapping device that determines whether an obstacle is present in a predetermined range of a target selected by a passenger and outputting obstacle information; a target attribute determination device that determines a target attribute based on the obstacle information and outputs target controllable item information; and a processor that generates control mode recommendation information selectable by the passenger based on the target controllable item information and outputs target attribute information and a selected control mode when control mode selection information is received from the passenger.

A vehicle speed control system includes a vehicle accelerator mechanism manually moveable between a plurality of positions, a detection arrangement configured to detect the position of the vehicle accelerator mechanism and to generate an output signal indicative of the position of the vehicle accelerator mechanism, and a vehicle speed controller configured to establish a speed of the vehicle as a function of the detected position of the manually controllable vehicle accelerator mechanism, and to use the output signal as an input speed control signal. A method of controlling speed of a vehicle by a vehicle speed control system is also provided.

Various embodiments relate generally to autonomous vehicles and associated mechanical, electrical and electronic hardware, computer software and systems, and wired and wireless network communications to provide an autonomous vehicle fleet as a service. In particular, a method may include receiving an indication of a sensor anomaly, determining one or more sensor recovery strategies based on the sensor anomaly, and executing a course of action that ensures the autonomous vehicle system operates within accepted parameters. Alternative sensors may be relied upon to cover for the sensor anomaly, which may include a failed sensor while the autonomous vehicle is in operation.

A configuration to output section information of an automatic driving section and a manual driving section and display data by which a time to reach each section is confirmable to a wearable terminal is implemented. A mobile device acquires the section information of an automatic driving section and a manual driving section on a traveling route, and estimates the time to reach each section and transmits the estimated time to an information terminal. The information terminal receives the transmission data from the mobile device, and outputs the section information of the automatic driving section and the manual driving section and the display data by which a time to reach each section is confirmable. Moreover, the mobile device determines notification timing of a manual driving recovery request notification on the basis of an arousal level, a position, or the like of a driver and transmits the determined notification timing to the information terminal, and the information terminal executes the manual driving recovery request notification at appropriate notification timing.

Embodiments of a system include a cloud computing center with one or more servers, storage coupled to the one or more servers, and a communication interface coupled to the one or more servers. A plurality of devices are communicatively coupled to the communication interface of the cloud computing center, so that the plurality of devices can communicate with the cloud computing center and with each other via the cloud computing center. At least one of the plurality of devices is a vehicle. A plurality of functional modules include instructions that, when executed by the cloud computing center, by at least one the plurality of devices, or by both the cloud computing center and at least one of the plurality of devices, enable functions including remote or direct interaction with the vehicle and, when there is direct interaction, personalization of the vehicle.

A vehicle control system (1) provided with a power generation unit (13) including an engine (10) and an electric motor (12), a storage battery (60), an electric motor for traveling (18), an acquisition unit (102) that acquires a schedule of an occupant of a vehicle (M), a destination prediction unit (104) that predicts a future destination including a destination which is not registered in the schedule on the basis of past and future schedules and date and time information acquired by the acquisition unit, a traveling planning unit (106) that generates traveling plan information indicating a traveling plan of the vehicle in the future schedule in accordance with a route to the destination predicted by the destination prediction unit, and a power generation control unit (110) that controls the power generation unit in the future schedule on the basis of the traveling plan information generated by the traveling planning unit.

A vehicle control system for controlling at least one subsystem of a vehicle; the vehicle control system comprising: a subsystem controller for initiating control of the or each of the at least one vehicle subsystems in one of a plurality of baseline subsystem control modes by setting at least one control parameter of the or each of the at least one subsystems to a predetermined, stored, value or state applicable to that baseline subsystem control mode, each baseline subsystem control mode corresponding to one or more different driving conditions for the vehicle; and input means for permitting a user to provide an input to the control system, wherein, for at least one of the plurality of baseline subsystem control modes, the control system is configured to allow a user to define, via the input means, a user-configured subsystem control mode based on one said at least one baseline subsystem control mode by adjusting the value or state of at least one of said at least one control parameters to a value or state other than the predetermined stored value or state applicable to that baseline control mode, the subsystem being configured to cause the subsystem controller to initiate control of the or each of the at least one vehicle subsystems in the user-configured subsystem control mode.

A system includes a non-transitory computer-readable storage medium. The non-transitory computer-readable storage medium has instructions stored thereon that, upon execution by a processor of a portable user device, cause the processor to wirelessly connect to a machine via a wireless transceiver of the portable user device, display a control interface for the machine on a user interface of the portable user device, receive a user input through the control interface regarding operation of a controllable component of the machine, and provide a command to the machine via the wireless transceiver based on the user input to facilitate remote operation of the controllable component of the machine.

Systems and methods are described herein for managing communications for a connected vehicle, such as between the connected vehicle and other connected vehicle and/or between the connected vehicle and infrastructure entities, such as providers of services to the connected vehicle. For example, a communication network, such as a network provided by a network carrier, may include various cloud engines or other network-based servers that manage, coordinate, and/or provision communications between the connected vehicle and other parties, such as vehicles, road devices, buildings, and other infrastructure entities.

A motor vehicle according to an exemplary aspect of the present disclosure includes, among other things, at least one power source. The motor vehicle is operable as a generator to supply power from the at least one power source to an auxiliary load. The motor vehicle also includes a controller configured to estimate a range of the motor vehicle based on a state of the at least one power source, and to command the motor vehicle to stop operating as a generator when the estimated range reaches a threshold range. A method is also disclosed.