Abstract: A robotic, wheeled surveillance vehicle capable of stair-climbing and traversing level surfaces. The vehicle comprises a rigid frame supporting a rotatable axle; an extension on which is mounted at least one surveillance device; a pair of spider assemblies rotatably supported adjacent opposite ends of said axle, each of said pair of spider assemblies supporting a plurality of rotatable wheels coupled to rotate in synchronicity; an inertial sensor supported on said frame in position to measure an angular position of at least one of said pair of spider assemblies relative to said frame; and an electric motor supported on said frame and operatively connected to drive said pair of spider assemblies to rotate.

Abstract: In an inverted pendulum type vehicle configured to travel on a ground surface while maintaining an upright posture under an inverted pendulum control, comprising a base frame supporting a propulsion unit, the propulsion unit including a main wheel configured to roll on the ground surface, and a seat unit provided on the base frame for supporting hips of a rider, the seat unit includes a saddle having at least a center located ahead of an axial line extending between a rotational center line of the main wheel and a gravitational center of the inverted pendulum type vehicle. Thereby, even when there is an obstacle on the ground surface behind the vehicle, the main wheel rolling on the ground surface is prevented from coming into contact with the obstacle, and the boarding of the rider on the vehicle is facilitated.

Abstract: A method of actuating a robotic mechanism having a first leg member rotatably coupled to a first side of a chassis and a second leg member rotatably coupled to a second side of the chassis. The method comprises positioning the first leg member and the second leg member generally about 180 degrees with respect to each other and effecting movement of the chassis by rotating both the first leg member and the second leg member with respect to the chassis.

Abstract: [Task] To allow a wheel that provides a performance required for use in an omni-directional vehicle to be manufactured in an efficient manner. [Solution] An annular member (51) comprises a C-shaped main body (61) and a complementary member (62) defining an endless annular shape jointly with the main body (61), a joint (63) between the main body (61) and complementary member (62) includes mating surfaces that are non-perpendicular to the cross sectional center line of the annular member, and the main body (61) and the complementary member (62) are fixedly joined to each other by using a threaded bolt (64) passed radially through the mating surfaces.

Abstract: When a vehicle is stopped on a slope, a brake is operated to stop rotation of a drive wheel so that no torque is applied thereto, and the posture of the body is controlled by moving an active weight portion so that stabilized stop state of the vehicle can be achieved without consuming a large quantity of energy. The vehicle comprises the drive wheel attached rotatably to the body, the active weight portion attached movably to the body, and a vehicle controller for controlling the posture of the body by controlling at least one of the drive torque imparted to the drive wheel and the position of the active weight portion, wherein the vehicle controller controls the posture of the body by controlling only the position of the active weight portion when the vehicle is stopped on a slope.

Abstract: A vehicle has a rotation-symmetrical, particularly spherical housing which is disposed about a rotational axis and has a convex drive and running surface. The housing is composed at least partially of transparent material, and has at least one door for at least one person to enter and exit. In the interior of the housing there is a seat for the at least one person, a drive for rotating the housing, and a device for control purposes. Bearings are provided in the rotational axis of the housing for rotatably mounting a lower seat structure receiving the seat. The drive is disposed on the lower seat structure and connected thereto. In order to improve the handling characteristics of such a vehicle, the seat is disposed displaceably laterally with respect to the lower seat structure.

Abstract: In a friction drive device comprising first free rollers and second free rollers contacting each other at the outer circumferential surfaces thereof to frictionally transmit power from the second free rollers to the first free rollers, in order to minimize the slippage between the first and second free rollers, minimize the power loss and cause the first free rollers to move as designed, an outer peripheral part of each first free roller defining an outer circumferential surface thereof has a different stiffness from that of an outer peripheral part of each second free roller defining an outer circumferential surface thereof.

Abstract: Heat generated by a drive source of a friction drive device such as an electric motor is allowed to efficiently dissipate to the atmosphere, and the friction drive device and an omni-directional vehicle using the same is designed in a highly compact manner. Left and right electric drive devices are placed on a central axial line of left and right rotatable drive members, and external teeth members serving as output members of the electric drive devices are directly connected to the respective rotatable drive members in a torque transmitting and heat transmitting relationship.

Abstract: A robotic two-wheeled vehicle comprising a connection body interposed between the two wheels are described. A drum can be coaxially located in a central region of the connection body and can support a hollow arm projecting radially from the drum. A tether can be inserted in the arm and connected to a second drum. Instruments and sensors can be accommodated in a case housed inside each wheel.

Abstract: A wheeled vehicle comprising a power-driven spider assembly for ascending and descending stairs. The vehicle includes an angular position sensor providing input to a controller operable to control a servo-motor to effectively lock the position of the spider relative to the frame, regardless of the hand truck's spatial orientation relative to a vertical plane, or any balancing of the hand truck. The angular position sensor provides input to the controller, which is programmed with predefined angular zones of instability, and causes the controller to accelerate rotation of the spiders through those zones when the wheeled vehicle is in the descent mode, to avoid instability of the hand truck. A hand truck may include a removable basket and/or a pivotable platform usable to transport loads.

Abstract: Method for controlling a vehicle that includes a support, at least one wheel, a platform coupled to the at least one wheel, a coupling structure having a support portion coupled to the support and a platform portion coupled to the platform that allows the support portion to move or slide fore and aft with respect to the platform portion, an actuator coupled to the coupling structure to control the position of the support portion relative to the platform portion, a drive coupled to the at least one wheel to deliver power to the at least one wheel to propel the vehicle and maintain the platform level, and a controller coupled to the drive to control the drive and coupled to the actuator to control the actuator.

Abstract: An apparatus and method for supplying operating voltages to a plurality of electronic devices is disclosed. A plurality of power supply modules of a modular power supply may output voltages to at least two electronic devices respectively. The apparatus may identify a failure of one of the power supply modules. The electronic device may be disconnected from the failed power supply module, and then reconnected to a functional power supply module of the modular power supply. switching a supplied voltage of the functional power supply module of the modular power supply, wherein the supplied voltage matches the set output voltage of the failed power supply module. If necessary, a supplied voltage of a functional power supply module may be switched to match the set output voltage of the failed power supply module.

Abstract: An omni-wheel based driving mechanism includes a spherical wheel, a pair of first omni wheels, and a pair of second omni wheels. The first omni wheels are arranged at two sides of the spherical wheel to space from each other by a predetermined distance in a first direction, so that the spherical wheel is rollably positioned between the first omni wheels. The second omni wheels are arranged at another two sides of the spherical wheel to space from each other by a predetermined distance in a second direction, so that the spherical wheel is rollably positioned between the second omni wheels. Therefore, a good driving efficiency can be obtained between the spherical wheel and the first omni wheels and the second omni wheels.

Abstract: A direction indicator system includes: an electromagnetic drive actuator that has a moving part that can slide back and forth, side to side, and diagonally; and a drive controlling unit that controls the sliding direction of the moving part, based on direction indicating information that is supplied from the outside.

Abstract: A method for forming a robotic vehicle. The method may involve forming a body and arranging a plurality of movable legs to project from the body for propelling the body over a surface. An actuator may be carried by the body to selectively engage and disengage different ones of the movable legs to cause a motion of the body, and thus the robotic vehicle, to travel over the surface.

Abstract: In a frictional drive device comprising a pair of drive disks (48) rotatably supported by a frame (10) around a central axial line (A) in a mutually opposing relationship, a pair of motors (64) supported by the frame for individually rotatively actuating the drive disks, a plurality of drive rollers (56) arranged along an outer periphery of each drive disk at a regular interval and each having a rotational center line so as to be rotatable along a plane which is neither parallel nor perpendicular to the central axial line, and an annular main wheel (84, 110) disposed approximately coaxially with respect to the central axial line and engaged by the drive rollers of the drive disks, the main wheel comprising an annular member (86, 111) and a plurality of driven rollers (92) supported along the annular member so as to be rotatable around a tangential line of the annular member, a resiliency is incorporated either in the main wheel or in the drive rollers so that a relatively large number of driven rollers can be

Abstract: A spherical drive system for a vehicle providing movement in multiple directions. The spherical drive system can be maneuvered either by a system of driven omnidirectional wheels or by an electromagnetic field. One embodiment includes two pairs of omnidirectional drive wheels working in complement to each other providing multi-directional movement by way of electronic motors which are wired to a controller. A spherical tire will reside within the shell and will be in direct contact with the omnidirectional drive and stabilizer wheels. The spherical tire will work in tandem with the omnidirectional drive and stabilizer wheels moving the vehicle in the appropriate direction. Another embodiment is driven by an electromagnetic field created with magnets placed inside the spherical wheel and electromagnets placed on an outer shell. The electromagnetic field will drive the spherical wheel moving the vehicle in the appropriate direction.

Abstract: A transporter for transporting a load over a surface. The transporter includes a support platform for supporting the load. The support platform is characterized by a fore-aft axis, a lateral axis, and an orientation with respect to the surface, the orientation referred to as an attitude. At least one ground-contacting element is flexibly coupled to the support platform in such a manner that the attitude of the support platform is capable of variation. One or more ground-contacting elements are driven by a motorized drive arrangement. A sensor module generates a signal characterizing the attitude of the support platform. Based on the attitude, a controller commands the motorized drive arrangement.

Abstract: The present invention provides an inverted pendulum type vehicle which can perform a turning movement with ease without requiring any additional device even though the vehicle is configured to travel on a single drive wheel. A substantially vertical principal axis of inertia of the vehicle is tilted rearward with respect to a plumb vertical line. As result, when a rider shift his gravitational center in either lateral direction and tilts the vehicle in the corresponding direction, the main wheel is caused to turn around the principal axis of inertia so that the main wheel is steering in effect, and the vehicle can be turned in a desired direction.

Abstract: A method and apparatus for permitting construction equipment, and particularly backhoe loaders, to be transported in the hold of a seagoing vessel within the interior of an enclosed cargo container includes front and rear rollers that temporarily replace the wheels of the equipment and allow it to be driven into and out of the container without any disassembly of the equipment.

Abstract: The present invention is an omni traction wheel system, which adopts an integrated differential mechanism to generate longitudinal and lateral traction forces. The omni traction wheel system may include a rotary device that delivers two individually controllable rotational forces, the differential output of which may drive a plurality of peripheral wheels to rotate laterally, and the common output of which may drive a pair of longitudinal plates to rotate longitudinally. Accordingly, the omni traction wheel system may travel in all directions.

Abstract: In a frictional drive device comprising a pair of drive disks each rotatably supported by a frame around a central axial line (A) in a mutually opposing relationship and configured to be individually rotatively actuated by a pair of actuators, a plurality of drive rollers arranged along an outer periphery of each drive disk so as to be rotatable along a prescribed plane of rotation, and an annular main wheel disposed at least approximately coaxially with respect to the central axial line and engaged by the drive rollers of the drive disks, the main wheel comprising an annular member and a plurality of driven rollers supported along the annular member so as to be rotatable around a tangential line of the annular member, each drive roller includes at least a pair of individually rotatable disk members coaxially disposed to each other and having different diameters, the diameters being selected so that the disk members engage the corresponding driven roller at outer peripheral parts thereof.

Abstract: The frictional relationship between the drive rollers of a pair of drive disks and the driven rollers of a main wheel is prevented from changing. A connecting mechanism (cross roller bearing) connects the two drive disks to each other so as to be rotatable to each other while restricting at least one of a radial displacement and an axial displacement between the two drive disks.

Abstract: Systems and methods for gravity independent gripping and drilling are described. The gripping device can also comprise a drill or sampling devices for drilling and/or sampling in microgravity environments, or on vertical or inverted surfaces in environments where gravity is present. A robotic system can be connected with the gripping and drilling devices via an ankle interface adapted to distribute the forces realized from the robotic system.

Abstract: According to a vehicle 1 of the present invention, coordinate systems of a past estimated value and an instantaneous provisional value of a two-dimensional floor inclination are conformed, by coordinate converting at least one of the “past estimated value” and the “instantaneous provisional value” of the two-dimensional floor inclination, using an orientation of the vehicle 1 or a rate of change thereof. Thereafter, a new estimated value of the two-dimensional floor inclination is calculated, by calculating a weighed mean value or a low-pass filter value using the past estimated value and the instantaneous provisional value of the two-dimensional floor inclination.

Abstract: An inspection apparatus for inspecting high voltage insulators is disclosed. The inspection apparatus includes a first platform having first and second linkages, at least one outer gripping mechanism having first and second arms extending outwardly from the first platform, a second slidable platform adapted to slide along the first and second linkages, and at least one inner gripping mechanism having third and fourth arms extending outwardly from the second slidable platform. The outer and inner gripping mechanisms are adapted to move between an open position where the insulator is received by the outer and inner gripping mechanisms and a closed position where the outer and inner gripping mechanisms engage the insulator.

Abstract: An inverted wheel type moving body according to the present invention includes a right chassis 17 and a left chassis 19 rotationally supporting wheels, motors 34 and 36 rotationally driving a right driving wheel 18 and a left driving wheel 20, a body 12 rotatably supported on the right chassis 17 and the left chassis 19 through a right arm 14 and a left arm 16, lower joint motors 65 and 95 disposed in the right arm 14 and the left arm 16 and varying vehicle height of the moving body 100, and a control unit 80 that controls the lower joint motors 65 and 95 to lower the vehicle height based on a fail signal 88 output when the inverted wheel type moving body is in an abnormal state.

Abstract: A drive unit for a vehicle is provided for use as a robot in pipe systems, cavities or the like. The drive unit includes at least one ring-like outer wheel and at least one driven magnetic wheel. The outer and the magnetic wheels have axes parallel to each other and are arranged eccentrically to one another, and engage one another such that when rotating relative to the outer wheel, the magnetic wheel delineates with its wheel axis a concentric circle lying within the outer wheel. In such a drive unit, stronger magnetic adhesion is enabled by the outer and magnetic wheels being arranged one behind the other in an axial direction. The engagement between the outer and magnetic wheels is effected by a circular, concentric disk connected securely against rotation to the magnetic wheel and rolls with its outer peripheral surface on the inner peripheral surface of the outer wheel.

Abstract: In a frictional drive device comprising a pair of drive disks (48) each rotatably supported by a frame (10) around a central axial line (A) in a mutually opposing relationship and configured to be individually rotatively actuated by a pair of first actuators (45), a plurality of drive rollers (58) arranged along an outer periphery of each drive disk each via a roller bracket (52) which is rotatable around a center line (B) extending in a radial direction at an angle with respect to the central axial line of the drive disks, each roller bracket rotatably supports the corresponding drive roller so as to be rotatable along a prescribed plane of rotation, and an annular main wheel (100) disposed at least approximately coaxially with respect to the central axial line and engaged by the drive rollers of the drive disks, the main wheel comprising an annular member (102) and a plurality of driven rollers (106) supported along the annular member so as to be rotatable around a tangential line of the annular member, eac

Abstract: The omni-directional drive device comprises a main wheel (2) comprising an endless annular member rotatable around a center of cross section perpendicular to a corresponding tangential line, electric motors (5R and 5L) for producing rotative forces around the rotation axis of the main wheel (2) and around the center of cross section perpendicular to a corresponding tangential line of the main wheel (2) and an arrangement (rotary members (4R and 4L) fitted with free rollers (3R and 3L)) for converting the rotational forces of the electric motors (5R and 5L) to the rotational forces around the rotation center of the main wheel (2) and around the center (C) of cross section perpendicular to a corresponding tangential line of the main wheel (2).

Abstract: A spherical infrared robotic vehicle (SIRV) is provided for remote reconnaissance. The SIRV includes a spherical shell, a chassis within the shell, an infrared sensor within the chassis and a set of wheels between the shell and chassis. The spherical shell has inner and outer surfaces. The chassis contains a platform, an electric motor and a power supply, and includes an infrared aperture. The infrared sensor mounts to the platform and disposed to receive an infrared signal through the aperture as infrared images. The sensor can be a plurality of infrared cameras mounted in separate directions. The set of wheels are driven by the motor and supported by the chassis. The wheels engage the inner surface and turn in response to the motor. Turning the wheels rolls the shell to propel the SIRV.

Abstract: Disclosed herein is a bidirectional moving micro-robot system. The bidirectional moving micro-robot system has a first body having a plurality of legs foldably/unfoldably connected thereto, a second body having a plurality of legs foldably/unfoldably connected thereto and a connection member having both end portions respectively connected to the first and second bodies. In the bidirectional moving micro-robot system, the length of the connection member exposed between the first and second bodies is extended or contracted.

Abstract: An apparatus and method are described for utilizing internally generated angular momentum for supplementing the propulsion of a mobile spherical vehicle capable of motion by rolling over terrain, thereby enabling such vehicles to climb steeper inclines and overcome larger obstacles. Torque generated by counter-rotating gyroscopes was used to supplement gravity generated torque produced by a pendulum drive propulsion system. Precession torque may be generated along a desired axis by changing the angular momentum of the gyroscopes while leaving its magnitude unaffected.

Abstract: In a robot apparatus having a base unit, a wheel unit of an opposed-two-wheel type mounted on the base unit and having driving wheels drivable so as to face each other, and an upper-body unit provided on an upper portion of the base unit and configured by concatenating one or more joints; a robot apparatus includes an opposed-two-wheel equivalent model, a robot-state observing unit, a control unit performing a control arithmetic operation for the opposed-two-wheel equivalent model, a transforming unit transforming a part of control target values calculated by the control unit to a control target value for the wheel unit, and a joint control unit controlling a joint-driving actuator of the wheel unit and also controlling a joint-driving actuator other than the joint-driving actuator.

Abstract: The present invention relates to a hands-free electric scooter including: a bottom housing; a steering housing disposed on the bottom housing; a steering shaft having a pressurizing plate mounted along the lower periphery thereof, a horizontal protrusion formed on one side of the pressurizing plate, a manipulating rod mounted on the underside of the horizontal protrusion, and a stopper mounted along the intermediate periphery thereof; a steering jig having an insertion hole formed at one side thereof, a micro switch mounted at the rear side of the insertion hole and having a grounding stick disposed at one side thereof, and an installation hole formed at the front side of the insertion hole; and a potential meter adapted to control direction changes of the hands-free electric scooter.

Abstract: A system includes a plurality of fluid chambers uniformly distributed about and in fluidic connection with a fluid reservoir, each fluid chamber having a valve and pressure sensor adjacent thereto, the valve configured to allow fluid flow between the fluid reservoir and the fluid chamber and the pressure sensor configured to determine the amount of fluid within the respective fluid chamber; means, adjacent to the fluid reservoir, for pumping fluid between the fluid reservoir and each of the fluid chambers; and a controller configured to control the means for pumping fluid and the valves using data from the pressure sensors. The means for pumping fluid, the valves, the pressure sensors, and the controller are contained within an inner housing and the plurality of fluid chambers are contained within an outer housing, which may be spherical in shape, and are external to the inner housing.

Abstract: A ball drive assembly for a vertical takeoff and land aircraft of the type having a plurality of supports extending outwardly from a central aircraft body. The ball drive assembly for one of the supports has a ball wheel housing containing a spherical, rigid ball, a drive shaft extending into the ball, a first driver for initiating rotating movement of the ball with respect to the ball wheel housing, and a second driver for initiating swiveling left and right movement of the ball so that it twists laterally of the ball wheel housing. Two motors are connected to the drivers, for operating them to rotate the ball with respect to the ball wheel housing, and effect both straight line movement and turning movement of the assembly.

Abstract: A robot includes a chassis, a motive subsystem configured to maneuver the chassis, a hopping actuator attached to the chassis and configured to launch the robot, and at least one leg pivotable with respect to the chassis to pitch the chassis upward at a selected launch trajectory angle. A control subsystem automatically actuates and controls the motive subsystem when the robot is airborne and uses the rotational momentum of the motive subsystem to control the attitude of the robot chassis in flight.

Abstract: A method and apparatus for permitting construction equipment, and particularly backhoe loaders, to be transported in the hold of a seagoing vessel within the interior of an enclosed cargo container includes front and rear rollers that temporarily replace the wheels of the equipment and allow it to be driven into and out of the container without any disassembly of the equipment.

Abstract: An apparatus capable of omni-directional movement including a belt layer made of a plurality of interlocking flexible rings and a surface layer made of a laterally inelastic and longitudinally flexible material that surrounds the exterior of the belt layer. The device has a bladder located in the interior of the belt layer that provides structural support for the belt layer and surface layer and a hub that is in contact with the surface layer and is connected to an axle. Longitudinal motion occurs as the bladder, the belt layer, the surface layer, and the hub rotate together. Lateral motion occurs as the belt layer and the surface layer rotate around the bladder. Longitudinal motion is induced by a plurality of electromagnetic curvilinear motor drive rings that are located around the hub and are in contact with the surface layer.

Abstract: An apparatus for locomotion includes an elongate body member defining a longitudinal axis and having oppositely disposed first and second body ends separated by a body lumen. A power source is operative to selectively provide motive power to the apparatus by changing a lateral cross-sectional area of the body member in at least one actuation location to produce at least one peristaltic wave propagated through the body member substantially along the longitudinal axis. The peristaltic wave is a substantially smooth wave. The peristaltic wave causes the body member to interact with an ambient environment and provide longitudinally oriented locomotion to the apparatus. A method for locomotion is also described.

Abstract: To provide a vehicle capable of performing a transition between a stable state and an inverted state with a simple structure. A vehicle in accordance with an aspect of the present invention is a vehicle that moves by inverted pendulum control, including a rider seat, a chassis, a right driving wheel, a left driving wheel, motors to rotationally drive the right driving wheel and the left driving wheel, a forward bar protruding forward beyond the chassis, a motor to rotational drive the forward bar, a footstep attached to the forward bar, and a control box to control the motor. The feet of a rider 80 are put on the footstep. The control box changes the vehicle to an inverted state by raising the footstep so that the footstep moves away from a ground, or changes the vehicle to a stable state by lowering the footstep so that the footstep comes into contact with the ground.

Abstract: Provided is a vehicle that can make tight turns without significantly changing an attitude of a rider, and is highly convenient in narrow places. A omni-directional one-wheeled vehicle comprises a vehicle body (7) and a secondary wheel (35) configured to contact a ground surface at a point displaced from a contact point of a driven road wheel (2).

Abstract: Provided is an inverted pendulum mobile vehicle such as a single-passenger coaxial two-wheel vehicle which is capable of turning with a small turning radius without causing discomfort to a rider or a vehicle occupant or causing a cargo or the like on the vehicle from shifting or falling off from the vehicle. The vehicle comprises a wheel supporting frame (12), a body frame (12) supported by the wheel supporting frame so as to be rotatable around a vertical axial line and carry a rider and or a cargo and a body coupler (52, 78, 70) that couples the body frame relative to the wheel supporting frame in a prescribed dynamic positional relationship.

Abstract: An amorphous robot includes a compartmented bladder containing fluid, a valve assembly, and an outer layer encapsulating the bladder and valve assembly. The valve assembly draws fluid from a compartment(s) and discharges the drawn fluid into a designated compartment to displace the designated compartment with respect to the surface. Another embodiment includes elements each having a variable property, an outer layer that encapsulates the elements, and a control unit. The control unit energizes a designated element to change its variable property, thereby moving the designated element. The elements may be electromagnetic spheres with a variable polarity or shape memory polymers with changing shape and/or size. Yet another embodiment includes an elongated flexible tube filled with ferrofluid, a moveable electromagnet, an actuator, and a control unit. The control unit energizes the electromagnet and moves the electromagnet via the actuator to magnetize the ferrofluid and lengthen the flexible tube.

Abstract: A magnetic adhesive and braking system for a remote controlled vehicle adapted for traversing across ferromagnetic surfaces of a steel shipping container including the vertical walls and ceiling. The magnetic wheel system allows the vehicle to traverse vertical grades. The magnetic braking system both securely holds the vehicle when stopped on a vertical surface, and exerts enough attractive force between the vehicle and the shipping container to allow a vehicle mounted drill to operate. The magnetic brake design uses mechanical advantage such that the force required to roll the vehicle vertically downward is heightened to the force required to detach the vehicle in a perpendicular vector from the container's surface.

Abstract: A microbot includes a spherical housing, first and second servomotors that are located internal to the housing and oriented horizontally and orthogonal to each other, and a plunger within the housing that selectively extends in the vertical direction. Castors are attached to each servomotor; and traction balls corresponding to each castor are placed so that each ball frictionally engages both a respective castor and the interior of the housing at the same time. As the servomotors rotate, the attached castors also rotate, which causes rotation of the traction balls and rolling of the housing, and results in translation of the microbot in the horizontal plane. As the plunger rapidly extends, it strikes the interior surface of the housing with sufficient force to cause a hopping motion of the microbot in the vertical direction.

Abstract: A support for a self-balancing vehicle that allows users to operate the vehicle while standing or sitting. The support includes one or more sitting platforms connected to the vehicle. The sitting platforms are rotationally movable between standing and sitting positions. The sitting platforms are connected to the vehicle by support bars that run vertically from the sitting platforms to the body of the vehicle. Displaceable rods moveably attached to the support bars contact the underside of the sitting platforms when in the sitting position and extend past the support bars to the standing platform to activate the vehicle. A plate system interposed between where the displaceable rods extend from the support bars and the standing platform help to evenly distribute pressure exerted by the support bars on the standing platform.

Abstract: A transporter for transporting a subject over a surface that may be irregular. The transporter includes a support platform for supporting a load, the loaded support platform defining fore-aft and lateral planes and characterized by a load distribution. A plurality of ground contacting elements are coupled to the support platform such that the transporter is statically stable with respect to tipping in the fore-aft plane. At least one of the plurality of ground contacting elements is driven by a motorized drive arrangement. A sensor module generates a signal indicative of the load distribution. Based at least on the load distribution, a controller commands the motorized drive arrangement.

Abstract: An apparatus and method for transporting a payload over a surface is provided. A vehicle supports a payload with a support partially enclosed by an enclosure. Two laterally disposed ground-contacting elements are coupled to at least one of the enclosure or support. A motorized drive is coupled to the ground-contacting elements. A controller coupled to the drive governs the operation of the drive at least in response to the position of the center of gravity of the vehicle to dynamically control balancing of the vehicle.