A system for a manual treadmill having a tread that rotates around a front axle and a rear axle and side rails on opposing sides of the tread includes a brake configured to slow rotation of at least one of the front axle or the rear axle, a controller, and a first presence sensor in communication with the controller, the first presence sensor positioned on a side rail and configured to detect a user on the side rail. The brake is not normally engaged during operation of the treadmill when the tread is moving and the first presence sensor does not detect the user on the side rail. The controller is configured to, in response to the first presence sensor subsequently detecting the user on the side rail, engage the brake.

The animation preparing device includes at least one processor. The processor acquires exercise data concerning an exercise done by a user or the exercise that the user is doing. In a case where there exists a plurality of causes for a characteristic point of the user that has been detected based on the acquired exercise data, the processor prepares, from the exercise data, a first user animation represented in a first direction of line of sight as an animation of the exercise done by the user or the exercise that the user is doing in order to indicate a first cause for the characteristic point, and prepares a second user animation represented in a second direction of line of sight that is separate from the first line of sight in order to indicate a second cause for the characteristic point that is separate from the first cause.

Control system of a cycling simulation device, said device comprising a support frame, with which a user carries out training by acting on the pedals of said bicycle, a flywheel rotating around a main shaft, connected to said coupling members, and a braking device, acting on said flywheel, comprising: a control logic unit, capable of connecting in transmission and reception with a remote device, by which a user can set one or more training parameters, and a torque sensor for detecting and sending to said control logic unit a signal related to the torque acting on said main shaft during the rotation of said flywheel, and said control logic unit being configured so as to adjust the braking force exerted by said braking device on said flywheel as a function of training parameters and of signal related to the torque acting on said main shaft detected by torque sensor.

An integrated multi-purpose hockey skatemill with a movable skatemill belt (2) comprising a stationary area of the artificial ice (1) with a front face of the work area wherein a movable skatemill belt (2) is built in by means of barrier-free transition areas with a system of spaced signalization/display elements (5) hung on the tiltable/sliding brackets (5a) at the frontal and lateral sectors with respect to the center of the movable skatemill belt (2). There is a safety restraint system (3) and a stabilization system (4) anchored above the movable skatemill belt (2). A tensile/compressive force measuring system (8) is suspended from above in the longitudinal axis of the movable skatemill belt (2). The said skatemill comprises an electronic control unit (9) ECU controlling the operation of the movable skatemill belt's (2) drive system, the system of signalization/display elements (5), the system of optical scanning cameras (6) and the tensile/compressive force measuring system (8). There are two puck feeders (7) located on the border line defining the front side of the work area. There is a hockey goal structure with target zones impact detection sensors located on the edge of the work force in front of the movable skatemill belt (2). Two laser markers (12) used to define the width of a skate track may be located on the stationary area of the artificial ice in front of the movable skatemill belt.

Disclosed are biofeedback methods and devices suitable for providing biofeedback useful for helping a user control an own breathing, for example, to help in inducing deep breathing, and such biofeedback devices further comprising a dispenser for dispensing an inhalable substance.

An exercise apparatus includes a frame and a load mechanism disposed on the frame. The load mechanism has a plurality of selectable weights with each of the selectable weights having an associated indicator device. A press is mechanically coupled to the load mechanism to displace a load based on a selected weight and a sensor is disposed to measure an extent and speed of displacement of the load. A processor is in communication with the sensor, and the processor is configured to determine an indicator signal to send to the indicator device of one of the plurality of selectable weights of the load mechanism based on received performance data, the indicator signal used to indicate which one of the plural of weights to select.

A variable-resistance exercise machine with network communication for smart device control and brainwave entrainment, comprising an exercise machine with a plurality of moving surfaces, that each provide an independent degree of resistance to movement, a sensor that detects movement and provides output to a controller, a brainwave entrainment manager that selects a brainwave entrainment frequency based on the sensor output, and a controller that receives an input from a user device, changes the operation of the plurality of moving surfaces based on the input, and sends the brainwave entrainment frequency to the user device.

An exercise device includes a base defining an inner volume and a top supported by the base, the top defining an aperture. The exercise device further includes a force sensor configured to measure force on the top and a motor disposed within the base and below the top, the motor including a cable extendable through the aperture. The exercise deice further includes a controller communicatively coupled to each of the force sensor and the motor. The controller is adapted to actuate the motor in response to forces applied to the top as measured by the force sensor. The controller may also actuate the motor in response to one or more additional parameters related to the speed or force with which the cable is manipulated (e.g., pulled by a user).

The present invention relates to systems, methods, and apparatus that facilitate exercise in vehicles. In particular, the present invention provides active exercise in passenger and navigation areas in vehicles by incorporating force sensors in the environment surrounding the passenger and/or navigator in the vehicle. The present invention applies the principles of isometric training and interacts with a remote or on-board computer platform to track, measure and provide instruction to the passage and/or navigator engaged in such isometric training.

An exercise device of the type including a frame with a first crank assembly rotatably coupled to the frame about a first axis and a second crank assembly rotatably coupled to the frame about a second axis. A control system may be used in communication with the first crank assembly and the second crank assembly, which may provide a synchronous movement of the first crank assembly relative to the second crank assembly. A pedal arm may be provided with a first end pivotally coupled to the first crank assembly and a pedal positioned on a second end. A crank link may be used with one end coupled to the second crank assembly and a second end coupled to the pedal arm. The crank link may be movable on the pedal arm which may provide varying paths of motion of the pedals.