An improved anti-fatigue mat is provided. The anti-fatigue mat includes a base member constructed from an elastomeric material configured to receive a foot or shoe of a user. A disk configured to rotate is provided, the disk having a disk top surface, wherein the disk top surface is flush or approximately flush with at least a portion of the base top surface. A substantial portion of the disk is embedded into the base member. The rotating disk is configured to rotate 360 degrees in both a clockwise and a counterclockwise direction enabling a user to rotate the disk in either direction via leg movements. A plurality of raised elements protruding from the top surface of the base member may be optionally provided.

An improved anti-fatigue mat is provided. The anti-fatigue mat includes a base member constructed from an elastomeric material configured to receive a foot or shoe of a user. A disk configured to rotate is provided, the disk having a disk top surface, wherein the disk top surface is flush or approximately flush with at least a portion of the base top surface. A substantial portion of the disk is embedded into the base member. The rotating disk is configured to rotate 360 degrees in both a clockwise and a counterclockwise direction enabling a user to rotate the disk in either direction via leg movements. A plurality of raised elements protruding from the top surface of the base member may be optionally provided.

Described herein are various embodiments of differential air pressure systems and methods of using such systems. The differential air pressure system may comprise a chamber configured to receive a portion of a user's lower body and to create an air pressure differential upon the user's body. The differential air pressure system may further comprise a user seal that seal the pressure chamber to the user's body. The height of the user seal may be adjusted to accommodate users with various body heights.

A foot-pedaling exercise apparatus by which a user can perform an effective foot-pedaling exercise is provided. A foot-pedaling exercise apparatus includes a crank, a main-body part configured to rotatably hold the crank, a link rotatably connected to the crank, the link including a pedal on which a sitting user puts his/her foot, a moving member disposed in the link, and a tilt table including an inclined surface on which the moving member slides.

A foot-pedaling exercise apparatus by which a user can perform an effective foot-pedaling exercise is provided. A foot-pedaling exercise apparatus includes a crank, a main-body part configured to rotatably hold the crank, a link rotatably connected to the crank, the link including a pedal on which a sitting user puts his/her foot, a moving member disposed in the link, and a tilt table including an inclined surface on which the moving member slides.

A sliding balance board has an eccentrically mounted center wheel as a pivotable central balancing member, a wheel with one-way sprag clutch bearings mounted near the left end of the board and a wheel with one-way sprag clutch bearings mounted near the right end of the board. A user balances himself/herself on the board, and yet slides the board to the left and right, back and forth by shifting his/her weight left and right, synchronized to the rocking motion of the eccentrically mounted center wheel.

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 method is disclosed for using an artificial intelligence engine to perform a control action. The control action is based on one or more measurements from a wearable device. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive the one or more measurements as input, and outputting, based on the one or more measurements, a control instruction that causes the control action to be performed. The method includes receiving the one or more measurements from the wearable device being worn by a user, determining whether the one or more measurements indicate, during an interval training session, that one or more characteristics of the user are within a desired target zone, and responsive to determining that the one or more measurements indicate the one or more characteristics of the user are not within the desired target zone during the interval training session, performing the control action.

A method is disclosed for using an artificial intelligence engine to modify resistance of one or more pedals of an exercise device. The method includes generating, by the artificial intelligence engine, a machine learning model trained to receive one or more measurements as input, and outputting, based on the one or more measurements, a control instruction that causes the exercise device to modify the resistance of the one or more pedals. The method includes receiving the one or more measurements from a sensor associated with the one or more pedals of the exercise device, determining whether the one or more measurements satisfy a trigger condition, and responsive to determining that the one or more measurements satisfy the trigger condition, transmitting the control instruction to the exercise device.

An improved anti-fatigue mat is provided. The anti-fatigue mat includes a base member constructed from an elastomeric material configured to receive a foot or shoe of a user. A disk configured to rotate is provided, the disk having a disk top surface, wherein the disk top surface is flush or approximately flush with at least a portion of the base top surface. A substantial portion of the disk is embedded into the base member. The rotating disk is configured to rotate 360 degrees in both a clockwise and a counterclockwise direction enabling a user to rotate the disk in either direction via leg movements. A plurality of raised elements protruding from the top surface of the base member may be optionally provided.