A transporter has a chassis, a left wheel positioned at the bottom of the chassis, a right wheel positioned at the bottom of the chassis, a drive train with a left wheel motor to control the left wheel and a right wheel motor to control the right wheel, and a control system to control the left wheel motor and the right wheel motor to implement self-balancing propulsion of the transporter. The improvement is the utilization of a left primary pulley in a left pulley arm assembly forming a first belt assembly to traverse an obstacle and the utilization of a right primary pulley in a right pulley arm assembly forming a second belt assembly to traverse the obstacle.

An electric vehicle may comprise a board including first and second deck portions each configured to receive a left or right foot of a ride, a wheel assembly disposed between the deck portions and including a ground-contacting element, a motor assembly mounted to the board and configured to rotate the ground-contacting element around an axle to propel the electric vehicle, at least one sensor configured to measure orientation information of the board, and a motor controller configured to receive orientation information measured by the sensor and to cause the motor assembly to propel the electric vehicle based on the orientation information. The electric vehicle may include exactly one ground-contacting element, and the motor may be a hub motor.

The disclosure discloses a device for detecting a driving mode of a self-balancing vehicle including: a detecting system comprising at least one detecting mechanism (102) each of which (102) is installed at each detecting point under a pedal (101) of the electric self-balancing vehicle and is used for detecting whether the pedal (101) deforms at a corresponding detecting point and sending the detection result to the controller; and the controller for judging whether the pedal (101) deforms according to the detection result sent by each detecting mechanism (102) and then determining current driving mode of the electric self-balancing vehicle. The driving mode includes a manned mode and an unmanned mode. The disclosure also discloses a method for detecting a driving mode of a self-balancing vehicle. The disclosure can prevent the electric self-balancing vehicle from entering an action state caused by a misoperation of the driver and eliminate potential dangers.

A method, system and apparatus for carrying a user including a board for supporting the user, a ground-contacting member coupled with the board, a motorized drive assembly coupled with the ground-contacting member and one or more sensors coupled with the drive assembly. In operation, the drive assembly adjusts the velocity of the ground-contacting member based on one or more distances of the board from a surface below the board as detected by the sensors. As a result, the system is able to maintain a desired velocity when ascending, descending or traversing uneven ground without the need for excessive and sometimes impossible tilting of the board.

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.

The yoke module is including wherein an elongated USB power cable, one or more yoke module sections accommodating access for the USB power cable and wire connectors to be threaded through one or more slotted openings and to exit out the top yoke module section, a first connection method to connect with the drive motor's lead cable harness directly to the USB power cable, a method to conceal and protect the drive motor's lead cable harness and the USB power cable by means of a coupling enclosure and yoke sleeve enclosure achieved through the yoke module's fabrication process. The yoke module also comprises a method for USB power cable to provide electricity power to drive a motorized wheel. The yoke module system comprises a second connection method for the yoke module to plug into auxiliary components including; a battery, a computer control system, and sensors for motion stability.

A self-balancing robot system comprising artificial intelligence characterized in that the robot is comprising a humanoid body or comprising a vehicle body. The humanoid body is used for service comprises; an articulated head comprising a voice system for user interaction, and a logic controller for facial imaging via a LED system and LED display monitor. The robot body comprising; a neck, two electromechanical arms with actuating hands used to achieve gripping objects; a pivoting trunk containing a computer operating system, the electrical control system including a batter bank and a battery charger; the lower portion of the body utilizing uni-robotic omniwheel or utilizing legs coupled to the robotic omniwheels or coupled to omnidirectional track wheels which work like skates. The robot system also comprises a computer operating system, a motion control system, an autonomous drive system, a wireless communication system working in combination with an attitude sensing system using state sensors, actuators and accelerometers to control pitch and balance thus allowing the service robot and service vehicle to work indoors and travel on common roadways and on smart highways.

A powered skateboard system comprising a skateboard deck having a top surface for supporting a rider of the inner-motorized omniwheel powered skateboard, a bottom surface configured to facilitate engagement with one or more inner-motorized omniwheel trucks, and a compartment adapted to store one of more components including a control system and wire connections disposed between the control device of the inner-motorized omniwheel powered skateboard; and one or more battery packs configured for a primary and a secondary back up power source and as well, a removable compartment cover configured to cover the opening formed by the compartment in the bottom portion of the powered skateboard deck. The control system comprising methodologies configured to control the power of the one or more inner-motorized omniwheel trucks by using a hand held wireless control device, the hand held wireless control device including one or more motion control buttons and toggle switches or by using a wireless phone device, the wireless phone device including one or more motion control buttons and toggle switches configured to transmit and to receive information associated with the operation of the inner-motorized omniwheel trucks.

A one-wheeled vehicle may include electric motors, a self-balancing system, and steering mechanism, wherein the electric motors and self-balancing system are disposed within the wheel of the one-wheeled vehicle. A computational resource such as a microprocessor-based controller receives input signals indicative of operation of a twist throttle and brake, and produces signals to adjust the tilt angle relative to the acceleration and thereby reduce the need for a rider to lean forward or backwards.

A portable two-wheeled self-balancing personal transport vehicle comprises a single support platform having first and second foot placement sections, one or more inertial sensors operable to provide pitch data for the platform. The first foot placement section and the second foot placement section are associated with a first wheel and a second wheel respectively controlled by a first and a second drive motor. At least one load sensor provides first load data for the first foot placement section and at least one load sensor provides second load data for the second foot placement section. Control circuitry is connected to the first and second drive motors, and operable to transmit to the first and second drive motors balancing signals for self-balancing the support platform housing in response to the pitch data, as well as one or more steering torque signals in response to the first and second load data.