A method is disclosed for using an artificial intelligence engine to interact with a user of an exercise device during an exercise session. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive data as input, and based on the data, providing an output. While a user performs an exercise using the exercise device, the method includes receiving the data from an input peripheral of a computing device associated with the user. Based on the data being received from the input peripheral, the method includes determining, via the machine learning model, the output to control an aspect of the exercise device.

An exercise device and methods for performing physical exercise that improve strength, conditioning, and flexibility of an operator in a functional way using multiple body positions and exercising multiple muscle groups while keeping the spine in a safe and natural position, being simple to manufacture and use, and being compact and portable. The exercise device includes an elongated member, a hollow member, handles, a foot board system, and at least one resistance band. A resistance band is secured to the elongated member and the hollow member, and slidable movement of the hollow member and the elongated member relative to each other by the operator stretches a resistance band, which creates resistance to the movement, thereby exercising, strengthening, and conditioning the operator. The operator may use the exercise device in a number of configurations to perform a number of exercises in a number of body positions.

The present invention relates to the field of medical devices. In particular, the present invention relates to an apparatus (10) for assisting the movement of a subject, such as a patient or disabled person, to train and strengthen the muscles of their body, said apparatus (10).

Apparatus and associated methods relate to a body positioning and support system having shoulder support surfaces (SSSs) and a lumbar support surface (LSS) offset downwards from a torso support surface (TSS). In an illustrative example, the TSS extends in a first plane along a longitudinal axis. An SSS may, for example, extend from each side of the TSS in opposite directions along a transverse axis orthogonal to the longitudinal axis in the first plane. The LSS may, for example, be distal to the TSS. The SSSs may, for example, each be defined by a first offset from the first plane towards a base plane. The LSS may, for example, be displaced from the first plane towards the base plane by at least a second offset. A neck support surface may extend from a proximal end of the TSS. Various embodiments may advantageously automatically position and support (targeted) body anatomy.

A hip adductor and abductor machine, wherein an action structure is installed on both sides of a device frame; the action structure comprises a pivot rotatably pivoted on the device frame, and rotating arms are installed on the pivot; one end of a resistance structure is connected to the device frame, and the other end thereof is provided with a connecting hook; when the device is in an abduction function state, two ends of a retractable elastic resistance rope are fixed on the rotating arms on both sides; when the device is in an adduction function state, a pin passes through the rotating arm and the connecting hook to connect the rotating arm and the resistance structure. The invention provides a machine with small volume, simple operation and dual functions of hip adduction and abduction.

A foldable multifunctional training equipment that comprises a foldable power cage (100); lower body training means (200); means for positioning a guided bar (300); at least two parallel towers of guided weights (400); and power transmission means (500) comprising a plurality of pulleys (501 to 505) and steel cables (507) that enable the folding of the equipment; and wherein, the foldable power cage (100) is the main structure of the lower body training means (200), as well as the means for positioning a guided bar (300), using the weights arranged in the parallel towers of guided weights (400); and wherein, furthermore, the lower body training means (200) and the guided bar (300) are connected by the power transmission means (500) to the towers of guided weights (400).

A stepper includes a base defining a horizontal plane, a first track structure coupled to the base and configured to translate along a first track, a first force receiving member coupled to the first track structure, a second track structure coupled to the base and configured to translate along a second track, a second force receiving member coupled to the second track structure, and a reciprocating mechanism coupled to the first track structure and the second track structure such that translation of the first force receiving member in a first direction causes the second force receiving member to translate in a second direction opposite the first direction.

A method is disclosed for using an artificial intelligence engine to interact with a user of an exercise device during an exercise session. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive data as input, and based on the data, providing an output. While a user performs an exercise using the exercise device, the method includes receiving the data from an input peripheral of a computing device associated with the user. Based on the data being received from the input peripheral, the method includes determining, via the machine learning model, the output to control an aspect of the exercise device.

A disorder detection system includes: a pair of left and right footrests configured so that left and right feet of a user are respectively placed thereon to perform an exercise of legs therewith; a pair of left and right slide mechanisms for enabling the footrests to slide in a front/rear direction with respect to a sitting part, the slide mechanisms including a resistance part for applying a resistance to the sliding; a moving mechanism for enabling the left and right slide mechanisms and the footrests to move independently of each other; an angle detection unit for detecting angles of joints of left and right lower legs of the user around a roll axis, a yaw axis, and a pitch axis; and a display unit for displaying the detected angles of the joints of the left and right lower legs of the user around the roll, yaw, and pitch axes.

An exercise machine comprising a resistance mechanism, a supporting frame, and a movable member which is movable relative to the supporting frame into and between a rest position and an extended position during performance of an exercise motion by a user. Movement of the movable member towards the extended position is resisted by the resistance mechanism. A stop device stops the movable member in the rest position, the stop device having an engagement member which engages and is able to translate along a stop surface on the supporting frame when the movable member is moved into the rest position.