A human-machine interaction somatosensory vehicle is provided. The human-machine interaction somatosensory vehicle may include a vehicle body and two wheels mounted on the vehicle body. The two wheels may rotate around the vehicle body in a radial direction. The vehicle body may include a support frame, two pedal devices mounted on the support frame, a controller, and a driving device configured to drive the two wheels. The support frame may be an integral structure rotatably connected to the two pedal devices. The two pedal devices each may include a pedal foot board and a first position sensor. The first position sensor may be mounted between the pedal foot board and the support frame, and configured to detect stress information of the pedal device. The controller may be configured to control the driving device to drive the two wheels to move or turn based on the stress information of the pedal devices.

In a frictional propulsion device comprising a frame, a main wheel including driven rollers rotatably supported by an annular core member about a tangential direction and a pair of drive disks each carrying drive rollers rotatable about a rotational center line at an angle with respect to both a tangential line of the drive disk and the rotational center line of the drive disk such that the drive rollers at least partly engage the driven rollers, each drive disk includes a hub rotatably supported by the support shaft, a disk member attached to a peripheral part of the hub, and holder beams arranged circumferentially between the hub and the disk member such that each holder beam is attached to the hub at a first end thereof and to the disk member at a second end thereof, each drive roller being rotatably supported by a corresponding adjoining pair of holder beams.

A travelling apparatus including a controller that adds, when receiving a turning instruction, a first correction amount calculated based on rider's centroid information to a first rotation amount of a first driving wheel calculated based on the turning instruction to rotationally drive the first driving wheel and adds a second correction amount calculated based on rider's centroid information to a second rotation amount of a second driving wheel calculated based on the turning instruction to rotationally drive the second driving wheel is provided.

An inverted two-wheel vehicle includes: an inverted two-wheel vehicle body; an acceleration sensor and a gyro sensor which are mounted on the same substrate; and an ECU. The ECU calculates a mounting angle error of the acceleration sensor with respect to the inverted two-wheel vehicle body based on an output value of the acceleration sensor obtained when the inverted two-wheel vehicle is brought into a stationary state in a state where a reference yaw axis of the inverted two-wheel vehicle is made coincident with a vertical direction, and corrects an output value of the gyro sensor by using the mounting angle error of the acceleration sensor with respect to the inverted two-wheel vehicle body as a mounting angle error of the gyro sensor with respect to the inverted two-wheel vehicle body.

A self-propelled, one-wheeled vehicle may include a suspension system configured to dampen up and down motion of a board relative to the axle of a central wheel assembly when the vehicle encounters obstacles and bumps on a riding surface. Illustrative suspension systems include a shock absorber, a rocker, a pushrod, bell cranks, and/or a swingarm that couple the axle to the board. The suspension system may be disposed completely below a foot deck of the vehicle.

A multiplexed battery set includes a plurality of battery units connected in series in such a manner that the battery units are bendable at connection positions, each of which is between each adjacent two of the battery units. Each battery unit includes a plurality of contacts. The battery set further includes a plurality of electrical wires respectively electrically connected between the contacts of each adjacent two battery units to electrically connect the battery units in series. The electrical wires has a length capable for keeping battery units in an electrically connected status when each adjacent two battery units are bent by an external force.

A foldable structure of an electric vehicle is disclosed. In the foldable structure, a frame defines a stowing space, and includes a connection base and a rotatable seat. The connection base has a chute and the seat includes a link rod. The wheel part includes two wheel casings, a tire and a driving device, and a containing space is formed between the wheel casings for containing the tire and the driving device. The wheel casings has a rotator cap protruded at tops thereof, and the rotator cap has an axle hole longitudinally cut therethrough, and the rotator cap is pivotally connected with the rotatable seat by the axle hole, whereby the link rod can be slid into the chute, and the two wheel casings and the tire can be laterally rotated into the stowing space, such that the electric vehicle can just occupy smaller space.

A two-wheel, self-balancing vehicle is disclosed. In one aspect, the two-wheel, self-balancing vehicle comprises a first wheel and a second wheel, the first wheel and the second wheel being spaced apart and substantially parallel to one another. The two-wheel, self-balancing vehicle further comprises a foot placement section connecting the first wheel and the second wheel. The two-wheel, self-balancing vehicle further comprises a set of position sensors in the foot placement section, the set of position sensors configured to generate inclination angle signals and velocity signals of the two-wheel, self-balancing vehicle. The two-wheel, self-balancing vehicle further comprises a first gravity sensor and a second gravity sensor in the foot placement section, the first gravity sensor and the second gravity sensor configured to generate weight signals and gravity angle signals. In addition, the two-wheel, self-balancing vehicle comprises a control logic configured to output control signals that control the movement of the two-wheel, self-balancing vehicle in response to the inclination angle signals, the velocity signals, the weight signals, and the gravity angle signals.

In some embodiments, apparatuses and methods are provided herein useful to transporting containers using an autonomous dolly. Some of these embodiments include systems for transporting containers along delivery paths comprising: an autonomous dolly having a microcontroller and a support portion configured to carry a plurality of containers; a mobile device with a microcontroller in communication with the microcontroller of the dolly; and one or more sensors in communication with the mobile device, the one or more sensors and mobile device configured to triangulate the location of the mobile device; wherein the dolly's microcontroller is configured to receive tracking information from the mobile device's microcontroller and to cause the dolly to follow the mobile device along a delivery path defined by movement of the mobile device from a starting point to an ending point.

A method for controlling a self-balancing vehicle to park is disclosed. The method is performed by the self-balancing vehicle and includes: sending a message of requesting for parking assistance to a surveillance camera device for controlling the self-balancing vehicle to park; receiving a first response message returned from the surveillance camera device according to the message of requesting for parking assistance, the first response message including parking instruction information for controlling the self-balancing vehicle to travel from a current location of the self-balancing vehicle to a target location; and controlling the self-balancing vehicle to travel from the current location to the target location and to park according to the parking instruction information.