A method of controlling a motorized wheelchair including a seat frame supporting a seat, a back frame to which the seat frame is detachably connected, a first main wheel and a second main wheel respectively installed at both lower ends of the back frame, an inclination detecting sensor which detects an inclination, and a controller which controls the main wheel and the second main wheel, includes receiving an input for a turning operation, calculating an inclination angle of a running ground by the inclination detecting sensor, and determining whether the inclination angle is greater than a reference angle.

A wheelchair can comprise: a frame comprising an upper portion and a lower portion that is coupled to the upper portion so that the upper portion is vertically adjustable with respect to the lower portion. A pair of drive wheels can be coupled to the frame. A plurality (e.g., a pair) of casters are coupled to the frame. Each caster can have a respective swivel axis. At least one caster of the plurality of casters can be configured to be locked to prevent swiveling about its respective swivel axis and unlocked to enable swiveling about its respective swivel axis.

Provided is a wheel which is inexpensive, light, and sufficiently rigid. A wheel 6a includes an annular rim 60 to which a tire 6b is externally fitted, a hub 61 which is arranged at a center portion of the rim 60 and to which an axle is connected, and a disk 62 which is attached with the rim 60 at a periphery portion and which covers one side of the wheel 6a. The disk 62 includes a planar portion 62a and a first rib 62b provided at a surface of one side of the planar portion 62a and extending in the radial direction. The planar portion 62a is provided with a first groove 62d at a surface of the other side at a position corresponding to the first rib 62b.

An electric locomotion apparatus including a dynamically stabilized vehicle including two wheels, the vehicle including a pivot arranged along a longitudinal axis and rotatable about the longitudinal axis. The pivot is configured to transfer a steering control to the wheels. A seat is positioned on the vehicle, wherein the seat is configured to accommodate a user affected by motor disability of the lower limbs, the seat being tiltable sideways by a lateral shift of the user's weight. The locomotion apparatus further includes one or more transmission device arranged between the seat and the pivot, the transmission device configured to transfer a tilting movement of the seat to the pivot. A first rod and a second rod can be centrally pivoted together, the second rod pivotally fixed to the vehicle, and the seat being associated with a second end of the first rod.

A system controls assistive technologies with an assistive tool for users with movement and/or communication disorders. The system includes an electronic communication interface, a biometric sensor, a calibration module and a processing unit. The interface presents users with stimuli associated with commands and/or information that the user might select. The sensor detects the user's biometric activity and generates a biometric electrical signal. During initial calibration, the calibration module records signal characteristics associated with a biometric electrical signal detected with voluntary biometric activity. The processing unit recognizes, based on the biometric electrical signal and the signal characteristics, the user's voluntary biometric activity and commands and/or information the user wants to select. The processing unit provides control signals to the interface and the assistive tool, based on the user's selection preferences. The interface presents stimuli based on the presentation control signal, if present, or presents a scan of stimuli.

Drifting karts in accordance with embodiments of the invention are described that include a front wheel drive train and rear caster wheels that can be dynamically engaged to induce and control drift during a turn. One embodiment of the invention includes a chassis to which a steering column is mounted, where the steering column includes at least one front steerable wheel configured to be driven by an electric motor, a battery housing mounted to the chassis, where the battery housing contains a controller and at least one battery, wiring configured to provide power from the at least one battery to the electric motor, two caster wheels mounted to the chassis, where each caster wheel is configured to rotate around a rotational axis and swivel around a swivel axis, and a hand lever configured to dynamically engage the caster wheels to induce and control drift during a turn.

A travel tool control method includes: capturing an eyeball image of a user; recognizing an eyeball action of the user based on the eyeball image of the user; and generating a travel tool operation instruction to instruct the travel tool to perform an operation corresponding to the eyeball action of the user. A travel tool control device includes a camera, configured to capture an eyeball image of a user; an image processing circuit, coupled with the camera and configured to recognize an eyeball action of the user based on the eyeball image of the user; and a control circuit, coupled with the image processing circuit and configured to generate a travel tool operation instruction to instruct the travel tool to perform an operation corresponding to the eyeball action of the user.

Provided is a wheel frame capable of measuring in detail the magnitude and the direction of a driving force while suppressing increase in weight and size of a driving wheel. A wheel flame (16a) includes a cylindrical hub (16c) into which an axle (11b) is rotatably inserted, a six-axis force sensor (16e) having an insertion hole (16e1) into which the hub (16c) is inserted, and an outer flange (16f) extending radially outward from an input section (16e2) of the six-axis force sensor (16e), wherein a hand rim (17) is attached to the outer flange (16f).

A personal mobility device includes a control system including a manually operated actuator, a first forward control valve having an inlet in fluid connection with a source of pressurized gas and an outlet in fluid connection with a first forward port of at least a first pneumatic motor, and a first rearward control valve having an inlet in fluid connection with the source of pressurized gas and an outlet in fluid connection with a first rearward port of the first pneumatic motor. Movement of the manually operated actuator controls actuation of the first forward control valve and the first rearward control valve and thereby flow of gas from the source of pressurized gas to the first forward port and the first rearward port.

A system 1 for controlling a powered personal mobility vehicle 8. The system includes an input module 2, a processing unit 4, and a motor controller 7. The input module 2 receives manual triggers 3 regarding the movement of the personal mobility vehicle 8. The processing unit 4 processes a location information 5 or a distance information 6 at a given point in time, and further, either generate an automatic trigger 19, and disable or curtail the functioning of the input module 2, or enable the functioning of the input module 2. The location information 5 is defined as a location of an obstacle co-located in an environment in which the personal mobility vehicle 8 is placed or being driven, and the distance information 6 is defined as the distance of the obstacle from the vehicle 8 at a given point in time. The motor controller 7 receives and processes manual triggers 3 or automatic triggers 19 and controls movement of the personal mobility vehicle 8.