Abstract: An inverted pendulum type vehicle (1) includes a lower frame incorporated with load sensor having an input portion 60 for receiving an external force and an upper frame (3) provided with a saddle 11 for supporting a load of a rider or a cargo and a grip handle (31) for enabling a user not riding the vehicle to support the vehicle (1), the upper frame being connected to the lower frame via the input portion of the load sensor. Therefore, in the vehicle including the lower frame supporting a propelling unit for the vehicle and the upper frame detachably attached to the lower frame, by using a single force sensor, not only the force acting on a load support portion of the upper frame can be detected in an accurate manner, but also the force acting on the load support portion when the user is transporting the vehicle can be detected.

Abstract: In an inverted pendulum type vehicle including a frame (2) incorporated with a propulsion unit (3) and a seat unit (4) provided on the frame, the seat unit (4) is moveable between a deployed position for supporting a rider and a retracted position different from the deployed position. Thereby, an object support unit for supporting an object such as a rider and a cargo can be positioned differently depending on the need so that the convenience and freedom in the use of the vehicle can be enhanced by preventing the object support unit from encumbering the user when not in use.

Abstract: A self-propelled device is provided including a drive system, a spherical housing, and a biasing mechanism. The drive system includes one or more motors that are contained within the spherical housing. The biasing mechanism actively forces the drive system to continuously engage an interior of the spherical housing in order to cause the spherical housing to move.

Abstract: In an inverted pendulum type vehicle (1) configured to travel on a ground surface (G) while maintaining an upright posture under an inverted pendulum control, comprising a base frame (2) supporting a propulsion unit (3), the propulsion unit including a main wheel (85) configured to roll on the ground surface, and a seat unit (4) provided on the base frame for supporting hips of a rider (H), the seat unit includes a saddle (63) having at least a center (C) located ahead of an axial line (B) extending between a rotational center line (A) of the main wheel and a gravitational center (Gt1) 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 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 moving device to move across a surface including a motor rolling motion apparatus is disclosed. The moving device is coupled to the motor and has a body with an outer surface. A dense population of fibrils protrudes from the outer surface, with each fibril having a free-end termination configured to establish adhesion to the surface by inter-molecular Van der Waals forces.

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.

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, a travel control module 81 controlling the motors 34 and 36 so as to follow calculated accelerations, and a posture control module 82 controlling the lower joint motors 65 and 95 to lower the vehicle height and change a position of a center of mass of the body 12 with respect to an axle in a front-back direction in accordance with the accelerations when the accelerations exceeds a certain range.

Abstract: A control method is proposed for a traveling dolly. The traveling dolly may include wheels driven by motors and a body supported by the wheels. The traveling dolly may further include a control computer commanding control command value to the motors, and a centroid of the body positioning above a rotation axis of the wheels. The control method may include the control computer estimating external force moment, which is a moment of inertia around the rotation axis of the wheels generated by external force applied on the body; a tilt angle of the body, which makes a gravity moment around the rotation axis of the centroid of the body balance with the external force moment, being set as a target body tilt angle; and based on the target body tilt angle, calculating a torque command value for the motors.

Abstract: Systems and methods related to construction, configuration, and utilization of humanoid robotic systems and aspects thereof are described. A system may include a mobile base, a spine structure, a body structure, and at least one robotic arm, each of which is movably configured to have significant human-scale capabilities in prescribed environments. The one or more robotic arms may be rotatably coupled to the body structure, which may be mechanically associated with the mobile base, which is preferably configured for holonomic or semi-holonomic motion through human scale travel pathways that are ADA compliant. Aspects of the one or more arms may be counterbalanced with one or more spring-based counterbalancing mechanisms which facilitate backdriveability and payload features.

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: Provided is a torque detection apparatus including a base portion, a drive portion, and a detection portion. The drive portion includes a rotor having a main axis in a direction of a first axis, and a stator configured to rotate the rotor around the main axis. The detection portion includes a strain body and a detection element. The strain body includes a first end portion to be fixed to the base portion and a second end portion to be fixed to the rotor, and is arranged concentrically with the rotor. The detection element is provided to the strain body so as to detect a strain of the strain body around the first axis with respect to the base portion.

Abstract: A rollover stability control system for a vehicle may include an object information device. An active suspension or an active steering system may be coupled to a wheel of the vehicle. The rollover system may include a lateral support system. A controller determines that an obstacle is an imminent tripping obstacle and raises or steers the wheel, to prevent the wheel from colliding with the obstacle, or deploys the lateral support system in response to a rollover notification signal and the determination. A rollover stability control system for a vehicle may include a chassis and a driving surface wheel. A wheel assembly is coupled to the chassis inward from the driving surface wheel relative to a longitudinal centerline of the vehicle. The wheel assembly contacts the driving surface when a roll angle of the vehicle is greater than a predetermined level.

Abstract: The present invention relates to a wheel suspension for mounting on a frame (3) of a vehicle, which, in its direction of propulsion, is arranged to be able to scale an obstacle (7), the wheel suspension (1) comprises a link element (9) arranged rotatably about a rotation point (R), to which rotation point (R), via the frame (3), can be applied a force (Gx) for propulsion, the link element (9) comprises a first and a second wheel axle (11, 13), the second wheel axle (13) serves as a moment axis (X) about which the link element (9) tends to rotate when a force (F) is applied to the first wheel axle (11) in the direction opposite to the direction of travel. The link element (9) acts as a lever arm by virtue of the rotation point (R) being situated at a distance from an imaginary straight line (L) intersecting the first and the second wheel axle (11, 13) and in a plane transversely to the extent of the moment axis (X).

Abstract: An apparatus and a method for robotic control that allows an unbalanced pendulum robot to raise its Center of Mass and balance on two motorized wheels. The robot includes a pair of arms that are connected to the upper body of the robot through motorized joints. The method consists of a series of movements employing the arms of the robot to raise the robot to the upright position. The method comprises a control loop in which the motorized drives are included for dynamic balance of the robot and the control of the arm apparatus. The robot is first configured as a low Center of Mass four-wheeled vehicle, then its Center of Mass is raised using a combination of its wheels and the joint located at the attachment point of the arm apparatus and the robot body, between the rear and front wheels; the method then applies accelerations to the rear wheels to dynamically pivot and further raise the Center of Mass up and over the main drive wheels bringing the robot into a balancing pendulum configuration.

Abstract: A wheel arrangement for a four-wheeled vehicle is comprised of a front wheel, two side wheels and a rear wheel, whereas the rear wheel is connected to the frame of the vehicle by a supporting base enabling the same to be steered freely while having a ground-touching point of the same to be biased from the axis of the supporting base by a distance, and the front wheel can be specified as a driving wheel, a free-rolling steering wheel or just a steering wheel with respect to actual requirement, and the two side wheels can be specified as a driving wheels or free-rolling wheels while enabling the axis of the two side wheels to be aligned to a straight line without sharing a same shaft.

Abstract: Disclosed are motorized litter transport kits and methods and devices relating thereto

Abstract: A vehicle (100) is disclosed. The vehicle may include a base portion (104) and a modular portion (112). The base portion may be a four wheel vehicle having an operator area (114) with seating for at least two occupants in a side-by-side arrangement. The modular portion may be coupled to the base portion resulting in a six wheel vehicle. The wheels (102) of the modular portion may be powered by an engine (500) of the base portion.

Abstract: A drive system is presented for controlling rotation of a sphere. The system facilitates holonomic motion of a drive with respect to a sphere such that a holonomic drive or drives may be maintained at a relative position with respect to a sphere. The motion of a sphere may be controlled by controlling the position of a drive with respect to the sphere. The drive may be controlled by way of a controller. A holonomic drive may be urged against a sphere by way magnetic interaction of the holonomic drive and a second structure. Also, a support structure is facilitated that allows a sphere to pass through a support column without breaks or interruptions in the sphere.

Abstract: A powered, gyroscopically balanced unicycle device to be used while standing, having leg contact surfaces which are made of a yielding, slightly soft material whose mild friction against the user's legs allows stable, precise control of the device without restraining the legs in any way. In one embodiment a single hubless wheel is driven by a friction drive mechanism which transmits torque from a motor through a drive wheel positioned below the foot platforms and in contact with the inner rim of the wheel. Various structures are provided for supporting the wheel and keeping it in place as it spins; absorbing small vertical movements of the wheel to prevent them from being transmitted to the foot platforms; enabling folding of the foot platforms; and facilitating carrying of the device by hand. Other embodiments are described and shown.

Abstract: [Task] Provided is a vehicle that can make tight turns without significantly changing an attitude of a rider, and is highly convenient in narrow places. [Solution] 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: The motor suitcase is a combination of a motorcycle and luggage suitcase. It is composed of a suitcase that is adequately dimensioned and ergonomically designed to safely carry the stored content as well as the driver. Adequate wheels with break mechanism are installed on the bottom side and a steering mechanism with commands to control the engine and breaks, connected to the front wheel, is installed on the upper side. It is driven by an electric engine or an internal combustion engine.

Abstract: Provided is an omni-directional drive device that does not complicate the arrangement for a power source for a drive source such as an electric motor, and achieves a high durability and an ease of maintenance. A drive force in a first direction is produced by a movement of a first moveable member (10) itself, and a drive force in a second direction is produced by the rotation of first free rollers (14) retained by the first moveable member, the rotation of the first free rollers (14) being caused by engagement with second free rollers (15) that are retained by a second moveable member (11) and rotative actuation of the second moveable member (11). Electric motors serving as drive sources may be mounted on base members (4 and 5).

Abstract: A mode of transpiration type employing a plurality of inner-motorized omniwheel apparatus comprising at least one electric motor or an ignited fueled motor, and supported by a zero degree rotating motorized yoke having hydraulic actuation, and managed by control system modes that enables a said vehicle type to transport an operator, a passenger and cargo in any given manner, and powered by a battery array that is charged by an electrical grid source, and by a renewable energy power system.

Abstract: A powered unicycle (100) having a wheel (105) driven by a motor (107) and a control system arranged to automatically maintain the fore-aft balance of the unicycle (100) via operation of the motor (107). The unicycle (100) also includes a handle bar (102), coupled to the wheel (105) by a pillar (101), which is operable to steer the wheel (105), and a rider-support (109) which is pivotable relative to the wheel.

Abstract: There is provided a motorized cycle comprising a frame, a seat mounted upon the frame, a plurality of suspensions mounted to the frame, a plurality of wheels each coupled to a suspension wherein the operation of the motorized cycle is based on the physical position and movements of the rider. Also provided is a suspension system for a motorized cycle comprising a plurality of suspensions each coupled to the frame of the motorized cycle, and a plurality of wheels each coupled to a suspension such that each wheel is able to move relative to the other wheels and the frame. According to another aspect, there is provided a rider positioning system for a motorized cycle comprising handle bars and a seat wherein the movement of the handle bars affects the movement of the seat.

Abstract: The present invention discloses an omnidirectional movement control system, having a move signal generator for generating a plurality of movement signals based on a plurality of first position signals and a plurality of second position signals, and an omnidirectional movement controller for generating a plurality of pulse width modulation signals and a plurality of motor direction change signals based on the movement signals and a plurality of motor encoding disc signals, and a driving circuit for driving motors to rotate a plurality of omnidirectional wheels based on the pulse width modulation signals and the motor direction change signals, such that a mobile platform can be moved in any direction and rotated in different directions, so as to provide excellent mobility and flexibility to the mobile platform.

Abstract: A frictional drive device comprises a pair of drive disks (48) each rotatably supported by a frame (2, 42) around a central axial line (A) in a mutually opposing relationship, and a pair of actuators (64) supported by the frame for individually rotatively actuating the drive disks and coaxially disposed with respect to the corresponding drive disks, a plurality of drive rollers (56) arranged along an outer periphery of each drive disk 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 (85) 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) 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.

Abstract: In a frictional drive device comprising a pair of drive disks (48) rotatably supported by a frame (10) around a central axial line (AL, AR) 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) 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) 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, the main wheel engaging an object to the actuated, the central axial line of at least one of the drive disks is tilted in an outward directio

Abstract: In an inverted pendulum type vehicle having a lower frame (22) and an upper frame (21) detachably joined to an upper end of the lower frame, the lower and upper frames each defining a hollow interior, a drive unit (3) is incorporated in the lower frame, and a battery unit (10) is received in the upper frame and configured to supply electric power to the drive unit via an electric unit (11) received in a narrow section intermediate between the upper and lower frames. Thereby, the vehicle may be of a compact and small foot print design. In particular, when this structure is applied to a vehicle using a main wheel having a relatively small width, by matching the upper part of the vehicle to have a corresponding small width, the overall profile of the vehicle may have a highly small width. Furthermore, the total weight of the vehicle can be relatively evenly distributed between the upper and lower parts for easy handling and control.

Abstract: An inverted pendulum type vehicle provided with a body, a pair of wheels and that is attached to the pertinent body and that is arranged in parallel, drive mechanisms and that separately rotate the pertinent pair of wheels and around wheel axes, and a control member that controls the drive mechanisms and, wherein: the body is provided with a base to which the pair of wheels and is attached, a column disposed upright from the base, and a load-supporting part that is attached to the column and that sustains a payload; the column is joined to the base via a shaft that extends in a non-parallel direction relative to the wheel axes, and is provided so as to be capable of sliding around the shaft; and the shaft is provided with an actuator which imparts torque to the column that slides around the shaft with an orientation that is the reverse of the sliding direction of the column.

Abstract: An inverted pendulum type moving body comprising: a base body; a moving behavior unit movable in all directions on a floor surface; an actuator driving the moving behavior unit; and a control unit controlling the actuator so that at least a tilt angle of the base body equals a predetermined target angle, the control unit also controlling the actuator so that the moving behavior unit moves along a predetermined trajectory.

Abstract: A self-propelled high-clearance vehicle includes a front half-chassis and a rear half-chassis placed one behind the other and assembled together by a pivot connection, the front and rear half-chassis respectively including firstly a front wheel set and a rear wheel set disposed in line one behind the other along the longitudinal axis of the vehicle, and secondly a first stabilizer wheel set on the left and a second stabilizer wheel set on the right located on either side of the longitudinal axis of the high-clearance vehicle; a driver's cab mounted on one and/or the other of the half-chassis; and an engine unit for driving the vehicle, mounted on one and/or the other of the half-chassis.

Abstract: A system and method for providing a fault tolerant vehicle dynamics control (VDC) is described. The system includes a fault tolerance module that receives an indication of a fault in at least one of the actuators of the VDC and selects a fault compensation mode to maintain the stability of the motor vehicle in light of the received fault indication. The fault tolerance module proceeds by diagnosing at least one fault in at least one of the actuators, selecting a fault compensation mode based on the detected at least one fault and the driving condition, and compensating for the at least one fault by optimally controlling remaining operable actuators according to the fault compensation mode.

Abstract: A variable wheel positioning vehicle has a wheel position changing mechanism and a wheel position control device to change a wheel position of a wheel with respect to a center of gravity of a vehicle body. The wheel position changing mechanism is arranged to move a suspension device along a movement path with respect to the vehicle body and to hold the suspension device at any position along the movement path. The wheel position control device issues a movement command to the wheel position changing mechanism that changes a wheel positioning distance between a center rotation axis of one of the wheels and the center of gravity of the vehicle body as measured in a direction parallel to an acceleration direction of the center of gravity of the vehicle body based on a traveling condition the vehicle.

Abstract: Systems and methods related to construction, configuration, and utilization of humanoid robotic systems and aspects thereof are described. A system may include a mobile base, a spine structure, a body structure, and at least one robotic arm, each of which is movably configured to have significant human-scale capabilities in prescribed environments. The one or more robotic arms may be rotatably coupled to the body structure, which may be mechanically associated with the mobile base and spine such that it may be deflectably elevated and rolled relative to the base simultaneously and independently. Aspects of the one or more arms may be counterbalanced with one or more spring-based counterbalancing mechanisms which facilitate backdriveability and payload features.

Abstract: A differential drive suspension for a robot with a high height to weight ratio

Abstract: An electric, drive system for floor conveyances with one or more vehicle chassis (3; 10, 11) in active connection with one another allowing relative movement and with at least one electric, drive motor and/or an electric, steering motor, with an electric transverter associated with each of these and an electronic, control system. At least one of these electric or electronic components is designed to be cooled by a liquid and is connected via an associated cooling circuit (5; 12) to at least one cooling device.

Abstract: A car having a rotatable wheel, the car being able to run by rotating the wheel, the car having a leg used by the car for walking, and an attitude stabilization section for stabilizing an attitude of the car.

Abstract: A mobile robot platform and a method for sensing movement of the same are disclosed, which utilize two omni-directional meter wheels perpendicular to each other and a magnetic sensing module for detecting a moving condition of the platform moving on a planar surface while transmitting the detected moving condition to a signal processing unit to calculate the position, velocity, angular position and angular velocity of the platform.

Abstract: A supporting member that carries at least 1 wheel and either rotates with the wheel to transmit mechanical power to and from it, and allows the wheel to rotate freely on it. The axle is an invention by itself and there is no prior art which has the axle attached to the housing. The axle and wheels can be removed and is therefore easier to ship. The axle can be used in a tricycle, trailer, caboose or any human or mechanical powered vehicle.

Abstract: A robot includes a second bumper that senses an obstacle having such a height that can be passed over. Thus, the robot can pass over the obstacle without avoiding it.

Abstract: The embodiments of the present invention disclose a spherical walking robot, the spherical walking robot comprises a spherical coronal; a spherical housing which has a surface groove; a walking and transmission mechanism in the spherical housing; a lift and transmission mechanism; mechanical arms located in the surface groove, and the mechanical arm comprises a little arm and an upper arm connected the little arm by an elbow joint motor. The embodiments of the present invention also disclose a spherical walking robot, the spherical walking robot does not comprise the lift and transmission mechanism, but a fastness mechanism and a rotating mechanism rotatably connected with the fastness mechanism.

Abstract: A moving object that moves through inverted pendulum control is equipped with a passenger seat in which a passenger sits, a chassis disposed below the passenger seat, a wheel rotatably mounted on the chassis, a drive portion that rotationally drives the wheel, and a weight unit that is provided at least partially in front of an axle of the wheel.

Abstract: A four-wheeled vehicle with a motorcycle body that allows the motorcycle body to be fixedly attached to metallic frame that includes a quartet of tires. The vehicle includes a metallic frame that has four “off-road” type tires attached to it. The vehicle also includes a motorcycle body which is essentially a motorcycle with the two tires stripped off of the body. The motorcycle body can be fixedly attached to the frame of the vehicle and can be connected to the drive train of the vehicle, allowing the engine on the motorcycle body to manipulate the drive train of the vehicle into turning the rear axle of the vehicle, thereby propelling the vehicle.

Abstract: A device for transporting a human subject over a surface. The device is a dynamically balancing vehicle having a control loop for providing balance. The device includes a platform defining a fore-aft plane. The platform supports a payload including the human subject. A ground contacting module is included which may include one or more wheels. A ground-contacting member is movably coupled to the platform. The platform and the ground-contacting module form an assembly having a center of gravity that is defined with respect to the ground-contacting member and which includes any loads on the device. The device further includes a support. The support may be a seat for supporting the subject and the support is coupled to the platform in such a manner as to permit variation of the position of the center of gravity in the fore-aft plane by translation and rotation of at least a portion of the support. In one embodiment, translation and rotation of the seat of the device are mechanically coupled together.

Abstract: This invention relates to wheeled vehicles and particularly to motorised road vehicles. The wheeled vehicle (10) includes two frames (12) for carrying road wheals (18, 20), the frames (12) being laterally spaced apart. A pair of road wheels (18, 20) are mounted on each frame (12) for supporting that frame (12) on the ground, the wheels (18, 20) of each pair being mounted for rotation about operatively more or less horizontal rotational axes which are spaced apart along the associated frame (12). A motor (36) is connected by a drive train (48, 28, 30, 32) to a rear wheel (20) on each of the wheeled frames (12). The wheeled frames (12) are connected together for synchronous tilting relative to the vertical, so that the camber angles of all the wheels (18, 20) change in response to lateral tilting of the frames (12).

Abstract: A detachable mobile seat includes a first part connected to a motor; a second part attached to the seat; and two links, each connected to the first part, the second part, and a wheel. The links transfer movement of the first part to the wheels. The first part includes a shaft connected to the motor, and two nuts disposed around the shaft that have screw threads in opposite directions and move along the shaft in response to operation of the motor. Each link includes a first link connected to the second part and to the nut, and a second link connected to the nut and to the wheel. The end of each second link that is nearest the wheel is rotatably connected to a connecting arm that has a rotating bar that rotates the wheel in response to operation of the links.

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: A self-propelled mechanical crawler adapted to move on a medium. One example of such a crawler includes a foot, a wave generator adapted to drive a periodic wave in the foot, and a wave transfer mechanism coupled between the wave generator and the foot. The wave transfer mechanism may be adapted to translate the periodic wave produced by the wave generator into a corresponding periodic deformation in the foot so as to generate forces in the medium to propel the crawler.