A training device may include a plurality of elongate shafts and at least one hinge structure interconnecting a pair of elongate shafts of the plurality of elongate shafts. The at least one hinge structure may be configured to allow a user to pivot the pair of elongate shafts relative to each other to select a desired angle between the pair of elongate shafts. In various embodiments, the at least one hinge structure comprises a hinge mechanism configured to be adjustable in discrete angle increments. Generally, the training device may be utilized in multiple configurations and may be adjusted and deployed in multiple different patterns to facilitate variable training exercises

A training device may include a plurality of elongate shafts and at least one hinge structure interconnecting a pair of elongate shafts of the plurality of elongate shafts. The at least one hinge structure may be configured to allow a user to pivot the pair of elongate shafts relative to each other to select a desired angle between the pair of elongate shafts. In various embodiments, the at least one hinge structure comprises a hinge mechanism configured to be adjustable in discrete angle increments. Generally, the training device may be utilized in multiple configurations and may be adjusted and deployed in multiple different patterns to facilitate variable training exercises

A computing system for determining osteogenic loading from an exercise apparatus for performing an exercise is provided. The exercise apparatus includes a loading interface, a frame, a linear adjustment system interposing between and fixedly coupled to the loading interface and the frame, and a sensor coupled to the linear adjustment system. A position of the loading interface of the exercise apparatus is adjusted through a movement of the linear adjustment system at one or more intermediate positions of a plurality of functional positions of the loading interface. A force exerted by a subject on the loading interface at the position in the one or more intermediate positions is received. A measurement of the force exerted by the subject on the loading interface at the position in the one or more intermediate positions from the sensor is obtained. A corresponding osteogenic loading for the force exerted by the subject is determined.

A device for an exercise apparatus includes a linear adjustment system and a sensor coupled to the linear adjustment system. The exercise apparatus includes a loading interface and a frame coupled to the loading interface for performing an exercise. The linear adjustment system fixes the loading interface of the exercise apparatus at any one of a plurality of functional positions in a functional range of the loading interface. The sensor measures the force exerted on the linear adjustment system. A correlating mechanism is used to correlate the force exerted on the linear adjustment system with the force exerted on the loading interface. The device allows exercisers to exert high or maximum loads in any one of a plurality of positions throughout their entire range of motion without first passing through a weak range of motion.

A treadmill may be configured for gait training and/or therapy with attachable/detachable barriers affixable to a belt and/or with a vertical obstacle module and/or with sensor systems, but without requiring hoists, harnesses, attachments to the treadmill or base, or frame, and/or excessively high treadmill frames, such as those that exceed the height of the person on the treadmill. The barriers on the belt are configured to modify movement of only one foot of a person on the treadmill. The treadmill may use a single, integral belt. Methods of gait training and/or therapy may involve such treadmills without excessive expense and without excessive modification of standard treadmill equipment.

A treadmill may be configured for gait training and/or therapy with attachable/detachable barriers affixable to a belt and/or with a vertical obstacle module and/or with sensor systems, but without requiring hoists, harnesses, attachments to the treadmill or base, or frame, and/or excessively high treadmill frames, such as those that exceed the height of the person on the treadmill. The barriers on the belt are configured to modify movement of only one foot of a person on the treadmill. The treadmill may use a single, integral belt. Methods of gait training and/or therapy may involve such treadmills without excessive expense and without excessive modification of standard treadmill equipment.

A fitness device for training the whole body. The device has coaxially arranged one over tubular elements of the same diameter, and an inner body disposed in the cavities 4′, 5′ and 7′, defined by the tubular elements. At the base of the inner body is a drive motor, providing rotational movement of the lower tubular element and the part of the inner body disposed in its cavity, which transmits the rotational movement and of the part of the inner body disposed in the cavity, by a spindle, at least two obstacles with identical construction respectively lower and upper, each magnetically connected to a sliding means, respectively detachably connected to sliders and of the inner body and a cover.

A treadmill may be configured for gait training and/or therapy with attachable/detachable barriers affixable to a belt and/or with a vertical obstacle module and/or with sensor systems, but without requiring hoists, harnesses, attachments to the treadmill or base, or frame, and/or excessively high treadmill frames, such as those that exceed the height of the person on the treadmill. The barriers on the belt are configured to modify movement of only one foot of a person on the treadmill. The treadmill may use a single, integral belt. Methods of gait training and/or therapy may involve such treadmills without excessive expense and without excessive modification of standard treadmill equipment.

A treadmill may be configured for gait training and/or therapy with attachable/detachable barriers affixable to a belt and/or with a vertical obstacle module and/or with sensor systems, but without requiring hoists, harnesses, attachments to the treadmill or base, or frame, and/or excessively high treadmill frames, such as those that exceed the height of the person on the treadmill. The barriers on the belt are configured to modify movement of only one foot of a person on the treadmill. The treadmill may use a single, integral belt. Methods of gait training and/or therapy may involve such treadmills without excessive expense and without excessive modification of standard treadmill equipment.

A treadmill may be configured for gait training and/or therapy with attachable/detachable barriers affixable to a belt and/or with a vertical obstacle module and/or with sensor systems, but without requiring hoists, harnesses, attachments to the treadmill or base, or frame, and/or excessively high treadmill frames, such as those that exceed the height of the person on the treadmill. The barriers on the belt are configured to modify movement of only one foot of a person on the treadmill. The treadmill may use a single, integral belt. Methods of gait training and/or therapy may involve such treadmills without excessive expense and without excessive modification of standard treadmill equipment.