A vehicle lane management system and a method of operating a vehicle lane management system is provided. The lane management system minimizes unnecessary driver warnings regarding lane departure and/or vehicle operation intervention actions to alter lane position when a vehicle is to be operated in a turn in conditions where the driver is or will be intentionally placing wheels of the vehicle outside of lane boundaries. The conditions for suppressing lane departure warnings and/or interventions include a vehicle speed being below a threshold speed and an upcoming turn radius being below a predetermined minimum turn radius.

A regenerative braking control system for a vehicle can include one or more user interface elements located in a cabin of the vehicle. The user interface element(s) can correspond to a plurality of regenerative braking settings. Each of the regenerative braking setting(s) can correspond to a different amount of regenerative braking torque to apply to the wheel(s) of the vehicle. The system can include a processor operatively connected to the user interface element(s). The processor can be configured to detect a condition, the condition being at least one of a weight of the vehicle, a center of gravity of the vehicle, a weight of a trailer operatively connected to the vehicle, and a center of gravity of a trailer operatively connected to the vehicle. The processor can be configured to cause the amount of regenerative braking torque for the regenerative braking setting(s) to be adjusted based on the condition.

A method for performing automatic maintenance of an autonomous vehicle is disclosed. The method includes receiving a maintenance request from the autonomous vehicle, wherein the maintenance request includes diagnostic data. Further, the method includes analyzing the diagnostic data to identify at least one recommended car service for the autonomous vehicle and comparing a vehicle location against a plurality of facility locations to identify a closest facility from a plurality of maintenance facilities, wherein the plurality of facility locations is associated with the locations of the plurality of maintenance facilities. Further, the method includes receiving a work schedule of the closest facility and generating an appointment reservation with the closest facility in the one or more facility locations based on the received one or more work schedules. Moreover, the method includes sending the appointment reservation to the autonomous vehicle.

Aspects and implementations of the present disclosure relate to performance and safety improvements for autonomous trucking systems, such as mitigation of blind spots in the field of view of a sensing system of an autonomous vehicle, using shielding by other vehicles in adverse weather conditions, and deploying a cooperative expansion of the sensing field of view using external sensing systems.

Aspects and implementations of the present disclosure relate to performance and safety improvements for autonomous trucking systems, such as reactive suspensions for maximizing aerodynamic performance and minimizing mechanical impact from road imperfections, automated placement of emergency signaling devices, and techniques of enhanced illumination of stopped and stranded vehicles.

A through the road (TTR) hybridization strategy is proposed to facilitate introduction of hybrid electric vehicle technology in a significant portion of current and expected trucking fleets. In some cases, the technologies can be retrofitted onto an existing vehicle (e.g., a trailer, a tractor-trailer configuration, etc.). In some cases, the technologies can be built into new vehicles. In some cases, one vehicle may be built or retrofitted to operate in tandem with another and provide the hybridization benefits contemplated herein. By supplementing motive forces delivered through a primary drivetrain and fuel-fed engine with supplemental torque delivered at one or more electrically-powered drive axles, improvements in overall fuel efficiency and performance may be delivered, typically without significant redesign of existing components and systems that have been proven in the trucking industry.

A method for controlling a hybrid electric driveline 2, comprising an internal combustion engine 3 and an electric machine 5 configured in parallel for driving a propulsion member 9, comprising the steps of: driving the driveline in generator mode, where the electric machine provides a charge current to a battery 11 and where the internal combustion engine provides positive driving torque to the propulsion member, and limiting the maximal available torque from the internal combustion engine to a predetermined torque limitation value depending on the rotational speed of the internal combustion engine.

A work vehicle includes an override operation sensor that senses override operation to carry out switching between an automatic driving mode and a manual driving mode and a selection device for selecting any one of the manual driving mode, a manned automatic driving mode, and an unmanned automatic driving mode, as the driving mode of a dump truck. A controller carries out switching from the manned automatic driving mode to the manual driving mode when override operation is sensed by the override operation sensor in the case in which the manned automatic driving mode is selected by the selection device, and continues the unmanned automatic driving mode when override operation is sensed by the override operation sensor in the case in which the unmanned automatic driving mode is selected by the selection device.

An embodiment driving control method includes determining whether a turning section is present ahead along a driving route of a host vehicle, determining a first turning radius with respect to a center of the host vehicle in response to determining that the turning section is present, determining, based on the first turning radius, a second turning radius required to prevent the host vehicle from deviating from a lane to an inside in a turning direction, determining a third turning radius with respect to an inner rear wheel in consideration of an overall width of the host vehicle, and controlling the host vehicle to travel along the driving route or to travel along a corrected route generated by correcting the driving route based on relative sizes of the second turning radius and the third turning radius.

A control system is provided for implementing multi-layer braking and retardation in a work vehicle that includes a hybrid electric drive system having an engine and one or more electric machines. The control system includes a braking and retardation system that dissipates energy generated by motion of the work vehicle, with the braking and retardation system including a brake resistor, an engine brake, and a transmission operable to provide transmission braking. A controller receives inputs on a braking torque demand and operational parameters of the hybrid electric drive system and the braking and retardation system, determines an amount of energy absorption necessary to meet the braking torque demand, and allocates the energy to be absorbed within the braking and retardation system according to a hierarchal energy allocation scheme based on the energy to be absorbed and the operational parameters of the hybrid electric drive system and braking and retardation system.