Systems and methods of a vehicle for sharing vehicle controls are provided. One example system is for sharing vehicle system control of the vehicle with a passenger. The system uses an on-board computer and communications circuitry of the vehicle. The communications circuitry is configured to use a wireless network for accessing the internet and the on-board computer is configured to enable the communications circuitry to provide a wireless connection to a portable device of the passenger of the vehicle. The on-board computer has access to one or more vehicle systems of the vehicle, and via the wireless connection, the on-board computer provides the portable device access to at least one graphical user interface, the graphical user interface includes input options that enable control of settings or functions of one or more of said vehicle systems. The on-board computer is configured to process information associated with a wireless signal of the portable device. The processing of the information is used to identify a location of the portable device inside the vehicle. The location of the portable device is utilized to identify a passenger seat of the vehicle and enable said control of settings or functions that pertain to an environment proximate to the passenger seat that was identified.

A vehicle position estimation apparatus according to the present invention includes a painted line recognition result processing unit configured to calculate whether the vehicle has made a lane change and a direction of the lane change when the vehicle has made the lane change, a vehicle lateral position calculating unit configured to calculate a lane where the vehicle is in travel and a vehicle lateral position that is a lateral position of the vehicle in the lane based on whether the vehicle has made the lane change, the direction of the lane change, and a lane connection relation, and an on-map vehicle position calculating unit configured to calculate an on-map position of the vehicle on the road based on a map information, the lane where the vehicle is in travel, the vehicle lateral position, and a forward travel distance.

Provided is a vehicle control device that is installed in a vehicle that is equipped with a display, including: a proximity communication module configured to perform communication with one or more terminals that are positioned inside of the vehicle; and a processor configured to select any one terminal from among the one or more terminals according to a preset reference, in which the processor controls the proximity communication module in such a manner that communication with a communication device which is positioned outside of the vehicle is performed using a wide area communication module that is installed in the selected terminal.

A travel control device comprising: a control unit configured to control travel of a vehicle; a first acquisition unit configured to acquire information regarding the surroundings of the vehicle; and a second acquisition unit configured to acquire vehicle information regarding another vehicle traveling in the same direction as the vehicle in a different lane from the lane that the vehicle is traveling in with at least a part of the other vehicle forward of the vehicle, the vehicle information regarding the other vehicle being included in the information regarding the surroundings of the vehicle acquired by the first acquisition unit, wherein, if the vehicle information regarding the other vehicle fulfills a condition, the control unit, in accordance with a state of approach of the vehicle to the other vehicle, performs control so that the vehicle decelerates.

An occupant support adapted for use in a vehicle includes a seat bottom, a seat back, and a sensory system. The seat bottom is coupled to a floor of the vehicle. The seat back extends upwardly away from the seat bottom. The sensor system is configured to monitor for fatigue of an occupant of the occupant support.

A fuel economy and comfort control apparatus is provided for a motor vehicle. That apparatus includes a plurality of sensors and a controller. The controller is configured to determine and advise an operator of the motor vehicle of the most fuel efficient mode of operating a climate control system of the motor vehicle to maintain occupant comfort while optimizing fuel efficient operation of the motor vehicle. A related method is also disclosed.

A method for determining a beneficial effect of a platoon comprises a leading vehicle and a following vehicle. In a first step, at least one first pressure acting on the leading vehicle is determined by means of an electronic processing unit. In a second step, at least one second pressure acting on the following vehicle is determined by means of the electronic processing unit. In a third step, a difference between the first and second pressures is determined by means of the electronic processing unit. In a fourth step, at least one benefit value is determined on the basis of the difference, by means of the electronic processing unit, the benefit value characterizing the beneficial effect of the platoon on at least one of the vehicles.

A regenerative braking control method of a hybrid vehicle may include: a vehicle condition determination operation of determining, by a controller, whether a vehicle speed and a driving mode satisfy conditions suitable for regenerative braking control of the hybrid vehicle; an accumulated count increasing operation of increasing, by the controller, an accumulated count of a reduction direction signal when the reduction direction signal is input from a two-way input device while the conditions are satisfied; an accumulated count reducing operation of reducing, by the controller, the accumulated count of the reduction direction signal depending on a count of the increase direction signal when the increase direction signal is input from the two-way input device while the conditions are satisfied; and a phased braking operation of increasing, by the controller, regenerative braking torque of a motor in phases depending on the accumulated count of the reduction direction signal.

An agricultural spraying machine having a defined transport width includes a chassis supported on the ground and configured to be set into motion in a forward direction, and a sprayer boom mounted on the chassis. A controller operably controls an actuator influencing the propulsion speed or driving direction of the chassis or the sprayer boom for reducing an oscillation of the sprayer boom in the forward direction. The controller triggers the actuator in response to a detected or expected oscillation of the boom due to a resulting change of speed or travel direction of the chassis or sprayer boom. An oscillation in an opposite phase to the detected or expected oscillation of the sprayer boom is induced in the sprayer boom adapted to lead to the reduction or cancellation of the oscillation of the sprayer boom.

A vehicle motion control system includes: a steering angle sensor for detecting a steering angle; a vehicle speed sensor for detecting a vehicle speed; a lateral acceleration sensor for detecting an actual lateral acceleration of a vehicle body; a reference lateral acceleration calculation unit configured to calculate a reference lateral acceleration from the steering angle and the vehicle speed; a required longitudinal force calculation unit configured to calculate a required longitudinal force for reducing a deviation of the actual lateral acceleration relative to the reference lateral acceleration; and a longitudinal force control unit configured to control an output of at least one of a brake and a power plant such that the required longitudinal force is generated.