In various embodiments, provided herein are systems, methods, processes, and devices for providing locomotive rehabilitation to a subject via one or more gait motions that substantially accurately mimic motions performed in healthy, natural gait cycles. The system may mimic natural gait motions via footplates and handles, and one or more linkage systems. In particular embodiments, the system may further include a motor unit and/or clutch for providing controlled forces assisting or resisting motions of a linkage system. Further, the system may include a tower for operating in a standing or seated position. In at least one embodiment, the system includes a body weight support system that provides offloading forces to a subject.

The subject matter of present disclosure teaches about a system of an artificial intelligence powered advance exercising facilities and method of working of the same. The system of an artificial intelligence powered advance exercising facilities of present embodiment eliminates need of permanent attached display over the exercise machines within the facilities by providing advance coupling of network enabled user devices of an exerciser, such as smartphone, laptop or any wearable smart devices to receive and display real time exercise data. Also, the system provides holding platforms for said user devices to safely hold the devices while user is exercising. Further, all the machines and equipment within the exercise facilities as well as surroundings such as wall of facilities of system are embedded with smart chips that monitors and transmits the real time exercise data of exerciser such as routine of exerciser, form and posture of exerciser, number of reps and count of dead weight etc. to the central artificial intelligence engine using local area network of exercise facility. The Artificial Intelligence engine, based on past exercise data, exercise regimen, health data and expert advices, prepares best workout routine and exercise schedule of the day for respective exerciser.

An exercise machine is provided. The exercise machine may include a frame, an adjustment assembly coupled to the frame and selectively movable relative thereto, a foot linkage arranged to reciprocally move in a closed loop path, and a handle linkage arranged to reciprocally move in a defined path. The adjustment assembly may include a pivot axis. The foot linkage may be pivotably coupled to the adjustment assembly at the pivot axis such that selective movement of the pivot axis relative to the frame alters the closed loop path of the foot linkage in use. Movement of one of the foot linkage and the handle linkage may cause corresponding movement of the other of the foot linkage and the handle linkage Actuation of the adjustment assembly may selectively move the pivot axis in more than one direction.

Electromechanical rehabilitation of a user can include receiving a pedal force value from a pedal sensor of a pedal; receiving a pedal rotational position; based on the pedal rotational position over a period of time, calculating a pedal velocity; and based at least upon the pedal force value, a set pedal resistance value, and the pedal velocity, outputting one or more control signals causing an electric motor to provide a driving force to control simulated rotational inertia applied to the pedal.

A pedal assembly for electromechanical exercise or rehabilitation of a user is disclosed and can include pedals to engage appendages of a user. A spindle supports each pedal and has a spindle axis. A pedal arm assembly is located between the spindle and a rotational axle of the equipment. The pedal arm assembly is radially offset from the spindle axis to define a range of radial adjustability for the pedal relative to the rotational axle. The pedal arm assembly can include an electrically-actuated coupling assembly to adjust the radial position of the pedal in response to a control signal, and regulate motion of the user engaged with the pedals.

In various embodiments, provided herein are systems, methods, processes, and devices for providing locomotive rehabilitation to a subject via one or more gait motions that substantially accurately mimic motions performed in healthy, natural gait cycles. The system may mimic natural gait motions via footplates and handles, and one or more linkage systems. In particular embodiments, the system may further include a motor unit and/or clutch for providing controlled forces assisting or resisting motions of a linkage system. Further, the system may include a tower for operating in a standing or seated position. In at least one embodiment, the system includes a body weight support system that provides offloading forces to a subject.

A lateral elliptical trainer includes foot support platforms and an adjustment system configured to adjust the amount of lateral movement of the foot support platforms. The adjustment system includes a cable operative to adjust the amount of lateral movement of the foot support platforms. The cable is coupled to an actuator that is controllable by a user to enable the user to set the amount of lateral movement of the foot support platforms.

A stationary exercise apparatus includes two connecting members each having an upper end guided to move along a circular path and a lower end coupled to a swing member, so that when the upper end moves along the circular path, the lower end moves along an arc-shaped path. Two supporting members are configured to support a user's feet, which are coupled between the upper end and the lower end of the respective connecting members and movable along a closed path. Two control members each is arranged between the corresponding supporting member and the corresponding swing member for guiding the second portion of the corresponding supporting member along a predetermined path, so that an angle formed between each supporting member and its corresponding connecting member varies as the corresponding swing member moves along the are-shaped path between a first endpoint and a second endpoint.

A drive mechanism for an elliptically-driven device includes a drive arm with a foot platform pivot assembly; a crank arm; a foot platform assembly pivotally coupled to the drive arm via the foot platform pivot assembly; a foot platform angle adjustment mechanism operably coupling the foot platform assembly to the crank arm so as to impart a foot platform angle of the foot platform assembly relative to the drive arm that varies during a stroke of the foot platform assembly.

A lateral glide elliptical exercise apparatus includes a frame defining a center line, a pair of pedal units disposed at two opposite lateral sides relative to the center line each including a pivoting block and a pedal shaft pivotally connected to the pivoting block, a damping unit for providing a damping resistance to the pedal units, and a pair of gliding guide units respectively mounted at the frame, each gliding guide unit includes a gliding guide, an actuation block and a linkage arranged so that the actuation block can be driven by the associating linkage to slide smoothly between an inner end portion and an outer end portion of the associating gliding guide when the pedal units are being alternately pedaled by the user.