An individual isokinetic pull force time performance exercise training system for monitoring power on each repetition in a workout on a piece of exercise equipment with a load cell and rotary encoder integrated into the equipment with wireless data transfer and signal processing for a display to provide relevant exercise measurements viewable to a trainer or trainee in a graphical format.

An apparatus 200 having a frame 202 forming a base 204 upon which extend first, second and third frame supports 206, 208, 210 for the seat unit 212, resistance unit 214 and crank unit 216, and guide unit 218 respectively

A method and apparatus for Activity Environment Generator (AEG) is provided. The AEG allows a user in a variety of settings such as: domestic settings, office chairs, TV chairs, train seats, airplane seats, domestic or hospital beds. The AEG is particularly useful in the fields of rehabilitation, physiotherapy, injury prevention, falls prevention, training and wellness in general and may also provide recreational and/or entertainment elements. The AEG provides dynamically controllable forces with which the user interacts in the course of his/her activity. In one aspect of the invention, the forces provided by the AEG are generated by a magnetic field. In another aspect of the invention, the forces provided by The AEG are generated by a pneumatic actuator. The AEG is optionally scalable and/or modular and, in specific embodiments, may include one or more of the following: a Remote Trainer, an AEG-Accessory, an AEG-Wearable, optimization by Big Data and machine-learning.

A method and apparatus for Activity Environment Generator (AEG) is provided. The AEG allows a user in a variety of settings such as: domestic settings, office chairs, TV chairs, train seats, airplane seats, domestic or hospital beds. The AEG is particularly useful in the fields of rehabilitation, physiotherapy, injury prevention, falls prevention, training and wellness in general and may also provide recreational and/or entertainment elements. The AEG provides dynamically controllable forces with which the user interacts in the course of his/her activity. In one aspect of the invention, the forces provided by the AEG are generated by a magnetic field. In another aspect of the invention, the forces provided by The AEG are generated by a pneumatic actuator. The AEG is optionally scalable and/or modular and, in specific embodiments, may include one or more of the following: a Remote Trainer, an AEG-Accessory, an AEG-Wearable, optimization by Big Data and machine-learning.

A power measurement apparatus for an exercise machine may include an optical sensing component and a pair of code wheels supported by the frame of the exercise machine. The pair of code wheels may include a first code wheel having a plurality of first windows and a second code wheel having a plurality of second windows that individually at least partially overlap respective ones of the first windows to define respective effective window, the width of which may vary responsive to the application of power via at least one moment-producing assembly. The optical sensing component is operatively associated with the pair of code wheels to detect variations in the width of the effective window and thus measure the power applied via the moment-producing assembly.

A cross country skiing exercise machine is disclosed. The machine has ski members slidingly mounted to a base frame and front and rear arm exercise units mounted towards the front and rear of the base frame, respectively. The front arm exercise unit has a front pair of flexible lines to be gripped by a user's hands to permit the user to reciprocally pull back on said front pair of flexible lines. The rear arm exercise unit has a rear pair of flexible lines having straps configured to be attached to the user's arms to permit the user to reciprocally pull forward on the rear pair of flexible lines. The front and rear arm exercise units are configured to apply a drag force to the front and rear pair of flexible lines, respectively. A rear leg exercise unit having flexible lines for mounting to the user's legs is also provided.

An exercise machine has a mobile base and an upright support extending upwards from the mobile base. An upper support assembly extends forward from an upper portion of the upright support and an exercise device is suspended from the upper support assembly at a location spaced forward from the upright support. The exercise machine may include a compact and safe counterbalancing gas spring mechanism that tends to move the exercise device away from the exerciser, and that requires a force to be applied to move an exercise device down towards the exerciser. The exercise machine may include an exercise device that is rotatable along a vertical axis, and may be coupled to an adjustable monitor for a wide range of uses. The exercise machine may be used by a exerciser lying supine, sitting in a chair or wheelchair, or standing in front of or adjacent the exercise machine.

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.

An exercise machine for performing triceps press exercises, including a moving user support that supports a user in a seated position. The exercise machine includes a linkage assembly that allows the moving user support to tilt as the user performs the triceps press exercise. As the user extends his or her arms from an exercise starting position to an exercise ending position, a user support frameand thus the user's torsoreclines progressively backwards. The user's natural reaction to this reclining sensation is to bring his or her head forward, which encourages the user to plant his or her lower back firmly into a stable position against a back pad and in turn reduces a risk of injury associated with excessively arching of the lower back.

An exercise machine for performing triceps press exercises, including a moving user support that supports a user in a seated position. The exercise machine includes a linkage assembly that allows the moving user support to tilt as the user performs the triceps press exercise. As the user extends his or her arms from an exercise starting position to an exercise ending position, a user support frameand thus the user's torsoreclines progressively backwards. The user's natural reaction to this reclining sensation is to bring his or her head forward, which encourages the user to plant his or her lower back firmly into a stable position against a back pad and in turn reduces a risk of injury associated with excessively arching of the lower back.