An embodiment in accordance with the present invention provides a device that transfers dexterous control of computers from hands to feet. The device of the present invention is a wearable foot based control interface for computers with a user interface that allows for a high level of customization. The device of the present invention provides an option to effectively control computers using ones feet. An innovative sensor design according to the present invention provides high sensitivity and robust usability. A graphic user interface according to the present invention allows for significant user customization of output commands and input sensitivity. The device of the present invention is wearable and provides comfort and intuitive usability.

An electric skateboard comprising: a deck; a front truck and a rear truck; a pair of wheels rotatably connected to each truck, wherein one or both pairs of wheels are driven by sensored motors; a communications module configured to receive control instructions from a wireless remote control and to transmit data to one or more external devices; a controller in communication with the communication module and the motors; and a battery supplying power to the motors, communications module and controller.

In an aspect, a powered vehicle is provided, and includes a body to support a rider. At least one wheel is rotatably coupled to the body to enable travel of the body over a travel surface. At least one motor is coupled to at least one of the at least one wheel to drive rotation thereof. A power source is coupled to the at least one motor to power the at least one motor. A remote sensor unit is wearable by the rider and configured to detect at least one of an orientation, a position, and movement of the rider and transmit sensor data generated therefrom. A motor control unit is coupled to the at least one motor and is configured to receive the sensor data and control the operation of the at least one motor based at least in part on the sensor data.

A self-propelled, one-wheeled vehicle may include a board having two deck portions each having a concave front footpad configured to receive a foot of a rider, and a wheel assembly disposed between the deck portions. The concave front footpad has a rider detection sensor in the form of a membrane switch conforming to the shape of the footpad (e.g., facilitated by one or more slots formed in the membrane switch). A motor assembly drives the vehicle in response to board orientation and rider detection information.

An ice-skating measuring apparatus includes an ice-skate blade holder and an ice-skate blade. The blade holder has a front beam column and a rear beam column. The blade includes at least one sensor configured to measure forces acting on the blade, and the blade is detachable from the blade holder.

A personal conveyance including a flexible substrate, a wheel and an electric motor mounted to a first wheel assembly, the wheel rotatably supported by the first wheel assembly and the electric motor configured to drive the wheel, wherein the first wheel assembly is mounted to the flexible substrate, a battery mounted to the flexible substrate and configured to power the electric motor, and a processor configured to control operation of the electric motor.

The disclosure relates to a skateboard and control method thereof. A skateboard deck is fixed on an axle of the skateboard, and a first sensor group and a second sensor group are sequentially arranged on the skateboard deck in a width direction. The method includes acquiring a first pressure value of the first sensor group and a second pressure value of the second sensor group; controlling the skateboard to turn to a first direction when the first pressure value is greater than the second pressure value and a difference value between the first pressure value and the second pressure value is greater than a first threshold, and controlling the skateboard to turn to a second direction when the second pressure value is greater than the first pressure value and a difference value between the second pressure value and the first pressure value is greater than a second threshold.

A mobility device is provided and includes a base panel that supports a passenger. A plurality of wheels are disposed at a plurality of points of the base panel and are coupled to the base panel to be rotated with respect to a vertical axis. A rotary portion provides a rotational force to rotate the wheel with respect to the base panel. Additionally, a braking portion is disposed on the rotary portion to adjust the plurality of wheels to be rotated with respect to the base panel or positions of the plurality of wheels to be fixed.

A backpack is disclosed for a personal transport vehicle including, in some embodiments, a back piece including a molded front panel, a securing device, a padded back panel, and a shoulder strap system. The molded front panel includes at least two ridges configured for placement of at least a portion of a body of the personal transport vehicle between the ridges. The securing device, which is attached to a first ridge of the ridges, is configured to cross over the molded front panel to a second ridge of the ridges to secure the body of the personal transport vehicle between the ridges when present. The padded back panel is configured to rest against a backpack wearer's back. The shoulder strap system includes a pair of shoulder straps extending from a top portion of the back piece, across the back panel, and to a medial portion of the back panel.

A self-balancing vehicle includes two vehicle bodies, respectively including a carrier assembly, a moving mechanism, a control assembly, and a power supply device coupled to the control assembly. The carrier assembly includes a frame and a foot platform coupled to the frame to form a cavity. The frame recess towards the foot platform defining a groove. The moving mechanism includes a wheel disposed on the groove side of the frame and a driving member. Part of the wheel is accommodated in the groove. The driving member drive the wheel to rotate relative to the frame. The control assembly includes a posture sensor detecting a tilt angle of the frame with respect to the vertical direction and a controller controlling a rotation speed of the driving member. At least one of the power supply device and the controller is accommodated in the cavity.