A method of adaptive control of a treadmill, the treadmill includes a base extending along a longitudinal axis, the base includes a first rotatable element and a second rotatable element adapted to rotate about respective rotation axes transversal to the longitudinal axis of the base. A physical exercise area operatively connects to the first and second rotatable elements. A motor is operatively associated with the first and/or second rotatable element. The motor is configured for rotating the first and the second rotatable and dragging in rotation the physical exercise surface. The method includes: determining by a data processing unit of the treadmill, a first electrical parameter of the treadmill representative of the interaction between a user and the physical exercise surface of the treadmill. The data processing unit controls the motor based on the first electrical parameter detected by the data processing unit.

Provided is a treadmill including a plurality of slats extending in a first direction and arranged in a second direction perpendicular to the first direction. The frame structure supports both ends of each of the plurality of slats to allow the plurality of slats to be movable in the second direction. The frame structure includes a central frame having a top portion having a curved shape. The frame structure further includes a first side frame and a second side frame respectively arranged on both sides of the central frame. A top portion of each of the first and second side frames has a shape corresponding to the curved shape of the central frame.

Aspects of the present disclosure relate to a gymnastic apparatus and method for cycling simulation having a transmission portion driven by pedals, through which a user may perform cycling training. The transmission portion may comprise a flywheel and a braking portion, which may apply a braking force to the flywheel. The apparatus may further comprise a control logic unit, through which training parameters may be set, and a sensor coupled to the control logic unit. The sensor may detect a signal relating to the torque acting on the flywheel and thereby send a signal to the control logic unit; the control logic unit may be configured to adjust the braking force of the braking portion applied to the flywheel, thereby adjusting the resistance to the pedals as a function of parameters set, as appropriate, and communicate information and adjust such changes via a feedback signal from the sensor.

A treadmill includes a frame; a front running belt pulley; a rear running belt pulley; a plurality of bearings coupled to the frame; a running belt at least partially supported by at least one of the front running belt pulley and the rear running belt pulley, the running belt including a running surface, at least a portion of which is curved; a support element coupled to the frame; and a safety device coupled to the running belt. The safety device is at least partly supported by the support element. The running belt freely rotates in a first direction of rotation relative to the frame, however, in a second direction of rotation, opposite the first direction of rotation, engagement between the support element and at least a portion of the safety device substantially prevents rotation the running belt relative to the frame.

A treadmill has a front or rear set of pulleys and a looped running belt. The pulleys rotate with the movement of the belt, e.g., when a user walks, jogs, or runs on the treadmill. The pulleys are mounted on a rotating roller tube so that the roller tube rotates with the pulleys. The roller tube is mounted on a stationary shaft using bearings on each side and a one-way device that allows the pulleys to rotate in one direction. The rotation direction corresponds to the movement of the top of the belt from the front to the rear of the treadmill. The one-way device prevents the pulleys from rotating in the opposite direction, preventing the top of the belt from moving from the rear of the treadmill to the front. The one-way device may be a sprag clutch. The treadmill may be a motor-less, curved treadmill.

A treadmill includes a running belt rotatable in a direction of motion and including a plurality of slats. At least one slat in the plurality of slats includes a top portion, a longitudinal rib extending away from the top portion and oriented along a longitudinal direction of the slat, and a bottom flange coupled to the longitudinal rib at or near a vertical bottom of the longitudinal rib such that the longitudinal rib is substantially positioned between the top portion and the bottom flange. The bottom flange extends away from the longitudinal rib on opposing sides of the longitudinal rib.

The present invention relates to a gymnastic machine having a closed circuit sliding belt comprising a base structure, a sliding belt, sliding according to a sliding direction installed on the base structure upon which a user performs a gymnastic exercise, a supporting structure coupled to the base structure, a first and a second handle for supporting the user, coupled to the supporting structure, a resisting device wearable by the user, the gymnastic machine being characterized in that each of the first and second handles comprises a respective coupling member for coupling with the resisting device.

There is provided a motorless treadmill. The motorless treadmill includes: a motorless track having a curved shape such that an inclination angle increases with respect to a ground surface toward a front end and a rear end, and configured to move around a closed path by a user's footsteps; and a pair of side covers disposed on two opposing sides of the motorless track, wherein the motorless track changes movement speed according to a location at which the user steps on the motorless track, and wherein, on at least one side cover of the pair of side covers, a speed-related indicator is disposed to indicate information related to the movement speed of the motorless track.

A system and method for using a body joystick to interact with a virtual or mixed-reality machines or software applications that uses a support arm to hold a device for attaching the body joystick to a user's body, a sensor for detecting movement, and a tether and actuator for providing feedback to the user about interactions with the virtual or mixed-reality machines or software applications.

A system and method for range of motion analysis while exercising, including methods for constructing user movement profiles based on repeated and typical user movements during exercises as are typical for an adult of a user's age, weight, etc., and capable of warning a user of unhealthy, unsafe, or anomalous movement patterns during exercise, using a balance trainer, range of motion analyzer, and a plurality of sensors in conjunction with an exercise device, in an effort to reduce health risks to users during exercise with an enhanced or mixed reality exercise device.