A transport system has a wheeled, steerable, self-powered, self-navigating carrier vehicle, having a substantially planar support frame, an on-board, rechargeable, battery-based power system, control circuitry, including GPS circuitry, on-board the carrier vehicle, adapted to drive and steer the carrier vehicle, and an upward-facing carrier interface adapted to the support frame, the carrier interface having first physical engagement elements, and a passenger pod adapted to carry both packages and persons, the passenger pod having a structural framework, a rechargeable, battery-based power system, and a downward-facing pod interface adapted to the structural framework, the carrier interface having second physical engagement elements. The passenger pod, placed upon the carrier vehicle, engages the downward-facing pod interface to the upward-facing carrier interface by the first and second physical engagement elements.

An exchange station has openings for drones, a passenger check-in/check-out bay for processing passengers, a drone connect/release bay, having apparatus adapted to manage passenger pods mounted on smart chassis, and a computerized control system in wireless communication with control circuitry in the drones and smart chassis, guiding smart chassis with mounted passenger pods and drones, to make the exchange of pods from the smart chassis to drones. A passenger entering the passenger check-in bay is loaded into a pod mounted on a smart chassis, the pod with passenger is transported to the drone-connect/release bay, and the pod is there joined to a bare drone and disconnected from the smart chassis, the drone leaving with the passenger pod to a destination, and the smart chassis traveling away from the drone connect-release bay.

A road vehicle convoy control method includes applying, on a hinge, a moment, an amplitude of which varies based on measured oscillations to absorb the measured oscillations. The moment is applied on the hinge by controlling an actuator of the hinge and jointly controlling: an electrical machine of a first wheel from a wheel set that belongs to part of a chassis that pivot in relation to another wheel because of the hinge to increase torque of the first wheel; and, simultaneously, an electrical machine of a second wheel from the same wheel set to keep the torque thereof constant or increase the torque of the second wheel less than the torque of the first wheel to apply the moment on the hinge in combination with the actuator.

A transport system has a first set of substantially parallel rails supported above ground level by support structures, a trolley having wheels mounted to a frame with the wheels engaging the rails, at least one wheel powered to move the trolley along the set of rails, a portion of the frame depending between the rails to a level below the rails, and a downward-facing latching interface on the depending portion of the frame, and a pod enabled to carry a passenger or parcels, or both, engaged by an upward-facing latching interface to the downward-facing latching interface of the trolley, such that, as the trolley travels along the rail set, the pod is carried along below the rail set.

A transport system has a wheeled, steerable, self-powered, self-navigating carrier vehicle, having a substantially planar support frame, an on-board, rechargeable, battery-based power system, control circuitry, including GPS circuitry, on-board the carrier vehicle, adapted to drive and steer the carrier vehicle, and an upward-facing carrier interface adapted to the support frame, the carrier interface having first physical engagement elements, and a passenger pod adapted to carry both packages and persons, the passenger pod having a structural framework, a rechargeable, battery-based power system, and a downward-facing pod interface adapted to the structural framework, the carrier interface having second physical engagement elements. The passenger pod, placed upon the carrier vehicle, engages the downward-facing pod interface to the upward-facing carrier interface by the first and second physical engagement elements.

The disclosure relates to a multimodal transportation apparatus for passenger transportation. The multimodal transportation apparatus comprises a passenger car. According to the disclosure, the multimodal transportation apparatus contains a motorcycle that is equipped with, and can be driven by an electric motor, and a securing apparatus to releasably fixedly secure the motorcycle to the passenger car. The motorcycle is arranged between a driver seat and a passenger seat, as seen in a direction of travel, in a secured operating state. At least a portion of a center console serves to support at least one body part of a rider of the motorcycle in an operating state, wherein the motorcycle is detached from the passenger car.

An electronic docking vehicle includes a vehicle body including a docking subject mechanism that docks with a first surrounding vehicle and a docking object mechanism with which a docking subject mechanism of second surrounding vehicle docks. A vehicle manipulating mechanism is provided in the vehicle body and includes a driving force generator providing a driving force to driving wheels. A steering manipulator controls a steering angle of the driving wheels. A braking manipulator generates a braking force in the driving wheels. A controller is configured to allow one vehicle to combine with the surrounding vehicle through the docking subject mechanism or the docking object mechanism.

A stackable mobile platform vehicle with a body with attached tires and wheels with a load bearing strength of at least 2500 pounds. In some instances the platform vehicle is powered by an electrical motor coupled to a generator which is powered by an internal combustion engine. A large flat load bearing deck on top of the vehicle is sufficient to support the weight of at least one additional stackable mobile platform vehicle. In some instances electricity produced by the generator can by exported from the mobile vehicle platform for use external to the mobile vehicle platform.

An apparatus and system for: combining independent driving vehicles into a single assembly for condensed, efficient, variable capacity transportation on common routes; and for separating into independent vehicles for flexibility on diverse routes. Connection logistics are exchanged locally via line of sight optical channel. Retractable coupling and mated coupling on opposing ends of the vehicles provide multiple degrees of freedom (DOF) to accommodate misalignment during initial dynamic engagement, and lock as rigidly coupled assembly with zero DOF. Mating vehicles' doors open during transit, permitting inter-vehicle movement and consolidation of passengers en route to urban locales, and release of empty vehicles. On return, independent vehicles combine to dense passenger vehicles from urban locales for redistribution of passengers in individual vehicles that later separate for diverse destinations. Slaved vehicle systems allow one vehicle to control coupled vehicles' systems of retractable suspension, coordinated steering, power sharing. Utility vehicles couple to assembly for service.

The present invention may include a processor that coupling vehicles into a linked vehicle, where each vehicle has a powertrain device with an attachment device, where the attachment device detaches the powertrain device from one of the vehicles. The processor causes the attachment device to detach the powertrain device from at least one of the vehicles based on determining that a weight of the linked vehicle should be reduced.