A method for updating a treatment plan. The treatment plan is associated with a user using a treatment apparatus to perform the treatment plan. The method includes receiving first data associated with a first diagnosis of the user. The method includes generating, based on the first data, an initial treatment plan to be performed on the treatment apparatus by the user. The method includes receiving second data associated with a first attribute of the user. The method includes generating, via an artificial intelligence engine, a machine learning model trained to generate an updated treatment plan based on the initial treatment plan and the second data.

Golf stroke training apparatus, as well as methods and systems to train a golfer to improve golf strokes, including putting strokes, wherein the golf stroke training apparatus provides a planar surface that can be levelled statically to the surface below it and can be adjusted by adding slope and/or pitch in quantifiable measurements and with a high degree of accuracy, wherein the repeatable golf stroke environments so provided permit repeatable and quantifiable golfer stroke actions and analysis and leading to golf stroke consistency.

Interactive/smart resistance band training systems include one or more resistance bands connected to a force sensing unit that registers the force exerted by a user on handles connected to the bands. The sensing unit operates effectively regardless of whether the user is training with one handle individually, or with two handles being pulled in parallel or non-parallel directions. The systems may correct the force readings to account for non-alignment between the force-measurement axis of the force sensing unit and the directions in which the user applies force to the resistance bands. The systems may guide a user through exercise sessions tailored to the fitness level of the user; may display the force readings, calories burned, and other performance parameters and goals on a continuous, real-time basis; may summarize the result of the exercise session; and may recommend subsequent exercise sessions based on the performance of the user.

A body weight support system includes a support track, a trolley, and a power rail. The support track has a first portion and a second portion. The trolley has a support assembly and a drive assembly. The support assembly is configured to support at least a portion of a body weight of a user. The drive assembly is configured to movably suspend the trolley from the first portion of the support track when the user moves along a first surface and is configured to movably suspend the trolley from the second portion of the support track when the user moves along a second surface separate from the first surface. The power rail is coupled to the support track and is configured to be in electrical contact with a portion of the trolley as the trolley moves along the first portion and the second portion of the support track.

There is provided a plank exercise device including a support portion adapted to receive arms or hands of a person and adapted to receive a display device, a destabilizer connected to the support portion, and a stationary base adapted to hold the destabilizer.

A monitoring system is disclosed for the regulation of the weight of a dumbbell, employable by a user for the execution of a gymnastic exercise, comprising a supporting frame, a dumbbell, placed on said supporting frame, equipped with a handle, having an axial development along an axis (R), capable of rotating around said axis (R), clockwise and counterclockwise, and equipped with a first end and a second end, a first plurality of weights, placed on said supporting frame, in which each weight is individually coupable to said first end by a first selection member, when said handle rotates one way, and detachable from said first end, when said handle rotates the opposite way, a second plurality of weights, placed on said supporting frame, in which each weight is individually coupable to said second end by a second selection member, when said handle rotates one way, and detachable from said second end, when said handle rotates the opposite way, said system comprising at least one detection device capable of detecting at least one physical phenomenon caused by the rotation of said handle to couple or detach one or more weights of said first and second plurality of weights to and from said handle.

The walking training device includes: a robot leg attached to one leg of a trainee; a treadmill; a load distribution sensor that detects a distribution of a load received from a sole of the trainee; and a walking state distinguishing unit that determines whether the one leg is in a swinging leg state; a control unit that performs a predetermined bending-extending control for the swinging leg state of the one leg by the robot leg when the one leg is in the swinging leg state; a measuring unit that measures a clearance between the one leg in the swinging leg state and the treadmill. The control unit changes control content of the predetermined bending-extending control so that the one leg does not contact the belt of the treadmill during extending control of the one leg, when the clearance is less than a specified value.

Provided is a highly reliable, cost-effective scattered object collection system that can determine the correct position of each scattered object on the ground, such as a ball, and efficiently collect scattered objects by reducing unnecessary traveling of an autonomous collector. The scattered object collection system includes an autonomous collector that performs a collecting operation by picking up balls B while traveling in a work area W and a collector management unit that manages the autonomous collector. The collector management unit acquires positional information on the autonomous collector, identifies an actual position where each ball B was picked up in the work area W using the acquired positional information, and allows the autonomous collector to perform a collecting operation in a place having a high density of balls B with higher priority than a place having a low density of balls B using the identified actual positional information on each ball B.

An exercise system may include an exercise mat; sensors integrated into the exercise mat, each of the sensors configured to sense when a force is applied to a respective portion of the exercise mat; and displays coupled to the exercise mat and configured to display indications corresponding to desired locations for body parts of a user in accordance with an exercise routine. On one or more of the displays, indications corresponding to desired locations of a user's body part may be displayed in accordance with a form of one of stored exercise routines; and one or more of the sensors may sense an application of force to the exercise mat. One or more of the displays may display at least one marker identifying a direction from a location of the sensed application of force to a display location of the at least one of the indications.

Provided is a weight exercise apparatus. The weight exercise apparatus includes an exercise main body in which movement occurs according to the user's weight exercise, a sensor module detecting movement of the exercise main body, and a processor configured to control a UI unit to display a UI element indicating an exercise state of a user corresponding to the detected movement on a UI screen, wherein the sensor module includes a first laser sensor comprising a first measurement accuracy and a first measurement frequency to detect weight setting of the exercise main body when the weight plate is in a stationary state and a second laser sensor comprising a second measurement accuracy lower than the first measurement accuracy and a second measurement frequency higher than the first measurement frequency to detect movement of the weight plate when the weight plate is in a moving state.