The disclosure provides a control device capable of smoothly performing a turning operation due to an external force for a mobile body having a movement operation part and a seat part of occupant. A control device which performs a movement control of movement operation parts a mobile body estimates a movement rotational force in the yaw direction according to a movement of the mobile body and a rotational driving force in the yaw direction according to a driving forces of an actuator, and estimates an external force rotational force, which is a rotational force in the yaw direction due to an external force applied to the mobile body, based on these estimation values. A turning operation of the mobile body is performed according to an estimation value of the external force rotational force and a maneuver operation of the mobile body.

An information processing device includes a registering unit, an obtaining unit, a predicting unit, a determining unit, and a vehicle relocating unit. The registering unit registers information on a destination where a predetermined event is held. The obtaining unit obtains current location information of vehicles movable around or within the destination. The predicting unit predicts, for each specific area, demand for the vehicles that are needed when the predetermined event is held at the destination. The determining unit determines, for each specific area, a difference between the number of available vehicles out of the vehicles of which current location information has been obtained by the obtaining unit and the number of vehicles predicted by the predicting unit. When the difference determined for each specific area by the determining unit is larger than a predetermined threshold, the vehicle relocating unit relocates the vehicles so as to reduce the difference.

A balancing board may include a first and a second platform section. Each platform section may include a housing formed of a bottom housing member and a top housing member. The top housing members may have a foot placement section or area formed integrally therewith. In one embodiment, the balancing board may include a water jet that includes a water receiving space and a water fog generating unit. More specifically, when the user stands on the balancing board, the weight of the user can trigger the water jet, wherein the water can be transported to the water fog generating unit from the water receiving space and the water fog can then be generated, so there is more entertainment effect when the user stands on the balancing board.

An auxiliary transport vehicle according to the disclosure comprises a drive unit and an attachment that is placed thereon, wherein the drive unit comprises just two wheels with a common axis of rotation and each with an electric drive, an electronic control device and an electrical energy storage device, and wherein the control device is embodied for actuating the drives in such a way that the auxiliary transport vehicle is kept in an upright position, and for autonomously driving the auxiliary transport vehicle to a specifiable destination and for following an external control device. The disclosure also concerns an auxiliary transport system and a method for operating an auxiliary transport vehicle.

Provided are a control method, a vehicle frame, a power driving assembly and a vehicle. The vehicle frame is configured to be connected with the power driving assembly, and the vehicle frame is provided with a manipulation assembly and a controller for controlling the power driving assembly. The control method includes that: after the vehicle frame is connected to the power driving assembly and a communication connection is established between the controller and the power driving assembly, the controller detects a manipulation instruction from the manipulation assembly; and in response to detecting the manipulation instruction from the manipulation assembly and determining that the manipulation instruction corresponds to the power driving assembly, the controller generates, according to the manipulation instruction, a control instruction for controlling the power driving assembly, and sends the control instruction to the power driving assembly.

A method for controlling a self-balancing vehicle, includes: acquiring a state of a parameter input from a user through a pedal of the self-balancing vehicle; and when the state of the parameter indicates that a change has occurred in the parameter, controlling operation of the self-balancing vehicle according to the change.

A control system for a tiltable vehicle may include a motor controller configured to respond to backward or reverse operation of the vehicle by hindering a responsiveness of the control system (e.g., proportionally) and/or eventually disengaging a drive motor of the vehicle. Accordingly, a user may intuitively and safely dismount the vehicle by selectively commanding reverse operation. In some examples, the backward direction may be user-defined.

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 truck, a tractor unit, a trailer, a tractor-trailer configuration, at a tandem, 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 mobile robot and drone device configured to dynamically allocate one or more task objectives and handling objectives, the mobile robot and drone device systematically couples to one another creating a hybrid robot-drone. The robot and drone array are utilized to work and obtain target objects in an environment, wherein the mobile robot and drone device comprise robotic arms and legs comprising propulsion drive wheels managed accordingly by AI system components including; an adaptive robot control system, an autonomous coupling system and an autonomous charging system configured with processors, and subsystems including; user interface, Cloud-Based Analysis and Data Usage Network, a sensor I/O devices including; LIDAR, RADAR, an altitude gyroscope sensors and cameras for scanning surrounding objects in an environment, and an identifier scanning system configured for identifying users, mobile robots, drone devices and target objects in a work environment and in a game environment. The work environment can include a consigned robot and drone array to work inside a cargo vehicle to gather cargo boxes and packages for delivery, and the array of working mobile robot and subsequently the drone device transports the boxes and packages by a flight plan and by a land-based drone device drive mode in flight restricted zones, and the game environment includes real-time gameplay, virtual reality and augmented E Sports game platforms.

An apparatus controller for prompting a rider to be positioned on a vehicle in such a manner as to reduce lateral instability due to lateral acceleration of the vehicle. The apparatus has an input for receiving specification from the rider of a desired direction of travel, and indicating means for reflecting to the rider a propitious instantaneous body orientation to enhance stability in the face of lateral acceleration. The indicating may include a handlebar that is pivotable with respect to the vehicle and that is driven in response to vehicle turning.