A system for controlling an engagement operation between first and second movable machines includes a separation sensor, a relative speed sensor and a controller. The separation sensor determines a separation distance between the first and second machines. The relative speed sensor determines a relative difference in speed between the first and second machines. The controller determines the separation distance between the first and second machines, decelerates the first movable machine when the separation distance is within a deceleration zone, determines a relative difference in speed between the first and second machines, and generates an engagement speed command to operate the first movable machine at a first ground speed equal to a second ground speed of the second movable machine plus a relative engagement speed when the separation distance is within a buffer zone.

A modular electric vehicle comprising a single module(s) with an electric driving system and a vehicle control unit, the modular vehicle is configured to be selectively articulated to a master vehicle and to be controlled from a selectable control source via the vehicle control unit either in a first, articulated mode, or in a second, autonomous mode. The control source may be selected to be in communication with a first gateway installed at the master vehicle or a second gateway installable at the modular vehicle. The modular electric vehicle may comprise a pair of single modules coupled to one another in tandem and in data and control communication with one another. The modules may each be configured to serve a master or a slave vehicle, so that any of the modules may serve a master vehicle, whenever required for the autonomous mode.

A vehicular display control device includes a memory; and a processor coupled to the memory, the processor being configured to: acquire a function allocation status of a multifunction switch capable of being allocated any press-implemented function, in order to display an image of a switch array including the multifunction switch on a display device, and display a first symbol in a display region corresponding to the multifunction switch in the switch array image in a case in which the multifunction switch has not been allocated a press-implemented function.

The present disclosure relates to a steering control system for a vehicle, a vehicle comprising such a steering control system and a method for operating such a steering control system for a vehicle. The steering control system comprises a frequency filter unit, a first control unit, and a second control unit. The frequency filter unit comprises a high pass filter and a low pass filter. The frequency filter unit is configured to receive a request for a steering angle and filter the request into a low-pass filtered request and a high-pass filtered request. The first control unit is configured to determine a first controlling torque based on the low-pass filtered request the second control unit is configured to determine a second controlling torque based on the high-pass filtered request. The first control unit is different of the second control unit.

A network hub device used for building a simple network configuration in an in-vehicle network system is provided. A network hub device (22) is provided in a vehicle body and is coupled to a trunk network through which a digital control signal is transmitted. A sub hub device (241, 242) performs input/output of a signal to/from an in-vehicle device provided in a partial body assembled to the vehicle body via a movable portion. The sub hub device (241, 242) is provided in the partial body and the digital control signal is transmitted/received between the sub hub device (241, 242) and the network hub device (22) via a wire harness passing through the movable portion.

A wire based control system for controlling a motor vehicle has an input having a transmitting unit for emitting signals for executing input commands, a first transmission channel for transmitting a first signal, a second transmission channel for transmitting a second signal, a receiving unit for receiving the signals, and an execution for executing the input commands.

A mobility service management system manages a mobility service utilizing a mobility service vehicle that runs via a stop position. A stop position reservation database indicates a reservation status of each stop position. A reservation request includes a target stop position and a target stop time specified by a user. The mobility service management system determines, based on the stop position reservation database, whether the target stop position is available in a target stop period including the target stop time. When the target stop position is available in the target stop period, the mobility service management system reserves the target stop position in the target stop period for a first mobility service vehicle assigned to the user. The first mobility service vehicle runs in accordance with a first operation pattern that arrives and stops at the target stop position within the reserved target stop period.

Systems including one or more sensors, coupled to a vehicle, may detect sensor information and provide the sensor information to another computing device for processing. A system includes one or more sensors, coupled to a vehicle and configured to detect sensor information, and a computing device configured to communicate with one or more mobile sensors to receive the mobile sensor information, communicate with the one or more sensors to receive the sensor information, and analyze the sensor information and the mobile sensor information to identify one or more risk factors.

The disclosure generally pertains to systems and methods for assisting a driver to travel through a drive-through lane of an establishment in an autonomous mode of operation. In an example method, a processor in a vehicle determines a location of the vehicle in a drive-through lane in various ways such as, for example, based on objects located in the vicinity of the drive-through lane, based on location coordinates, and/or based on a geofence defined around the establishment. The processor may then place the vehicle in an autonomous mode of operation and instruct the driver of the vehicle to refrain from touching vehicle driving control components such as the steering wheel, the brake pedal, and the accelerator pedal. The vehicle autonomously then moves through the drive-through lane in a stop-and-go mode of movement at a controlled speed while executing lane-centering and collision avoidance.

An early-warning system, method, and apparatus for steering of a two-wheeled vehicle, and a corresponding two-wheeled vehicle including a display apparatus. The system includes: a first control system and a second control system both operating independently and exchanging data between each other in real time; the first control system is configured to: monitor a steering state of the two-wheeled vehicle in real time and generate steering state data; generate early-warning state data based on the steering state data; transmit at least part of the steering state data and the early-warning state data to the second control system in real time; and control corresponding components of the two-wheeled vehicle to operate according to control instructions received from the second control system and internal preset instructions; and the second control system is configured to: control a display of the display apparatus based on the steering state data and/or the early-warning information.