Aspects involve an exercise system in which various methods may be practiced. The exercise system facilitates a method of controlling an exercise on a motorized exercise device where the method involves, at a remote computing device, accessing an exercise template including fields associated with an exercise, obtaining a first exercise definition from matching the first exercise template with a first of a plurality of predefined exercises, and providing an exercise definition to a local device for controlling a motorized exercise device, the exercise definition based on matching the exercise template with a first of a plurality of predefined exercises, the exercise definition including a parameter associated with a resistance force that will be used to control a motor of the motorized exercise device when the first exercise is performed at the exercise device.

An electromechanical device for rehabilitation includes pedals coupled to radially-adjustable couplings, an electric motor coupled to the pedals via the radially-adjustable couplings, and a control system including a processing device operatively coupled to the electric motor. The processing device configured to, responsive to a first trigger condition occurring, control the electric motor to operate in a passive mode by independently driving the radially-adjustable couplings rotationally coupled to the pedals. The processing device also configured to, responsive to a second trigger condition occurring, control the electric motor to operate in an active-assisted mode by measuring revolutions per minute of the radially-adjustable couplings, and cause the electric motor to drive the radially-adjustable couplings when the measured revolutions per minute satisfy a threshold condition, and responsive to a third trigger condition occurring, control the electric motor to operate in a resistive mode by providing resistance to rotation of the radially-adjustable couplings.

The present disclosure relates to an exercise machine for performing a gymnastic exercise, comprising a first exercise device, in turn comprising at least one first cable, and at least one first handle, coupled to said first cable, to allow a user to perform a gymnastic exercise, and a second exercise device, in turn comprising at least one second cable, and at least one second handle, coupled to said second cable, to allow the user to perform a gymnastic exercise, said exercise machine further comprises a first actuator, connected to said first cable, for exerting a drive or resistant torque on said first cable, a second actuator, connected to said second cable, for exerting a drive or resistant torque on said second cable, and a logic control unit, connected to said first actuator and said second actuator, for adjusting said drive or resistant torque.

Methods and systems for controlling a force generator of an exercise apparatus are described wherein the method comprises determining or receiving angular positions of a rotatable axle of an exercise apparatus when a force is applied to a force receiving structure of the exercise apparatus, the rotatable axle being part of a mechanical power transmission system connecting the force receiving structure via the rotatable axis to a force generator which is controlled by a computer based on a kinematic model, the kinetic model representing equations of motion of the exercise the apparatus; determining or retrieving first geometrical scaling values associated with the angular positions and incorporating the first geometrical scaling values into the kinematic model to form a first modified kinematic model, the first geometrical scaling values being associated with a non- circular gear of a first predetermined non-circular geometry; and, determining applied force values for the angular positions, each applied force value representing a force that is applied to the force receiving structure; and, controlling the force generator based on first resistive force values to mimic an exercise apparatus comprising a mechanical power transmission system including the first non-circular gear, the first resistive force values being computed using the first modified kinematic model and the applied force values.

A wearable device and an exercise support method performed by the wearable device are disclosed. The exercise support method includes receiving exercise setting information associated with a lower body muscle that is selected by a user input, determining a torque profile to be applied to the wearable device based on the received exercise setting information, and operating an actuator of the wearable device based on the determined torque profile.

An interactive exercise system with apparatus and methods to optimize muscle strength for rehabilitation, to improve or maintain fitness, and to enhance the performance of athletes. The system uses an electronically controlled linear actuator to generate resistance against the muscular force exerted by the user. The system includes sensors configured to detect acceleration, speed, velocity, position, direction of movement, duration, and the force applied by the user. A control system preferably continuously monitors the sensors, and instantaneously adjusts the adaptive actuator. This provides a proportional counterforce to the user force throughout the entire range-of-motion. A display panel allows the user to interact with the system in real-time. The objective of the user is to synchronize the exercise performance with a selected target goal, by correlating the user's movement relative to a position on a display panel.

A method for controlling breathing of a user during workout with an exercise machine is provided. The method includes acquiring, by a data processing unit of the exercise machine, at least one parameter representative of a physical exercise being performed by the user with the exercise machine, determining, by the data processing unit of the exercise machine, an indication of the breathing to be followed by the user while performing the physical exercise based on the acquired at least one parameter representative of the physical exercise, and providing the user, by the data processing unit of the exercise machine, with the determined indication of breathing. An exercise machine implementing the method for controlling breathing of the user during workout is also provided.

An exercise accessory includes a load bearing element. It further includes a haptic actuator. In response to an indication of an event pertaining to a load on the load bearing element, the haptic actuator is configured to generate a vibration pattern corresponding to the event. Different events are associated with different vibration patterns.

The present invention provides a compact, wearable and portable self driven rehabilitation device which is cost effective, light weight, portable, easy to use and customizable to fit as needed. It provides real-time mirroring effect for better visual feedback.

A method for operating a seat system, where the seat system includes a vehicle seat having a plurality of controllable moveable elements integrated into a seat cushion that forms a seat surface and/or into a seat back, includes prompting, during an activated muscle training program, a user on the vehicle seat to exert a pressure with a specific body region of the user on a predetermined region of the vehicle seat in which at least one of the plurality of controllable moveable element is arranged and determining a local and a temporal deviation between a pressure exerted by the user as an input signal and a specification as an output signal.