A portable exercise device provided includes: a base disc, two pulley assemblies, a support plate, and a fan wheel assembly. A support plate is disposed on the base disc, the two pulley assemblies are provided on the base disc, and the fan wheel assembly is provided on the support plate, so that the fan wheel assembly and the two pulley assemblies are vertically arranged on top of each other, thereby reducing the overall volume. More preferably, because the volume is reduced, the user can arbitrarily move and hang the portable exercise device at the desired position, and because the portable exercise device of the invention can be hung at different positions, which allows the user to train different muscles according to the different positions.

Provided is an exercise therapy device capable of more appropriately adjusting a load on an exercising person. An exercise therapy device (10) includes torque detection means (13) and control means (12). The torque detection means (13) is configured to detect a torque applied to a rotation portion (11). The control means (12) is configured to execute processing for changing a motion speed of the rotation portion (11) based on a force reference and the detected torque.

The present invention relates to circadian rhythm management. In order to improve circadian rhythm management, an apparatus is provided that uses an alternative exercise-based concept and personalized approach for managing or controlling personal circadian rhythm and optimizing sleep onset.

An exercise management and reporting system includes a weightlifting rack having a plurality of vertical members. Each of the vertical members include bar support brackets for receiving a barbell and weighted plate combination. Tracking sensors are positioned along the vertical members to track the movement of the barbell during an exercise. A control unit having a memory and wireless transmitter are provided along the rack. Weight sensors are positioned within each of the bar support brackets, and a wireless accelerometer is positioned along the barbell. The system also includes an exercise management application that receives the exercise data from the control unit and recommends and adjusts exercise workouts based on the received exercise data for each system user.

An adaptive active training system includes a motion module, a sensing module and a control module. The motion module includes a training unit and a motor connected to the training unit. The motor is configured to bring the training unit to move along a motion trajectory. The sensing module is configured to sense a physiological signal of a user when the user uses the training unit. The control module is connected to the motion module and the sensing module. The control module is configured to calculate a position of the training unit on the motion trajectory, obtain a threshold value corresponding to the position based on a motion model, and determine whether a magnitude of the physiological signal is greater than the threshold value.

The present application relates generally to computer software, mobile electronics, wireless communication links, and wearable monitoring systems. More specifically, techniques, systems, sensors, circuitry, algorithms and methods for wearable monitoring devices and associated exercise apparatus are described. A garment borne sensor system may acquire data on a user's performance during exercise, for example. The data may be analyzed in real time and feedback may be provided to the user based on the analysis. Analysis may be used to alter behavior of the user and/or an apparatus the user is engaged with during an activity, such as exercise, conditioning, therapy, etc. A piece of exercise equipment may be instrumented and in communication with the sensor system or other system and may be controlled in real time to adjust its settings to affect the user during the exercise routine. Communication between the sensor system and other systems may be wireless.

Embodiments of the present invention are directed to an adjustable-incline climbing wall. The climbing wall comprises one or more climbing panels supported by a frame and a system for adjusting the incline of the frame to provide a climbing wall of a desired incline. The incline of the climbing wall may be adjusted by activating an actuator, which extends the upper portion of the frame a distance from a support wall, tilting the climbing wall to a desired incline. When the climbing wall is substantially vertically oriented, the system for adjusting the incline of the climbing wall may extend only a small distance from the support wall so that the adjustable-incline climbing wall has a relatively small footprint. In some embodiments, the climbing wall may also comprise one or more fitness accessories that can brought to an optimal height for a particular user through adjustment of the climbing wall incline.

A stair and slide assembly includes a stair portion including a plurality of stairs, a slide portion including a slide with an entrance and an exit, and an assist bar positioned proximate the exit of the slide to assist a user with pivoting from the exit of the slide to the stair portion. The slide has a first portion extending substantially linearly from the entrance of the slide at an angle and a second portion extending from the first portion to the exit of the slide. The second portion transitions the slide from the angle of the first portion to substantially horizontal. The exit of the slide is configured to be positioned at a target height above a ground surface. The target height is between about 18 inches and about 30 inches.

A fitness monitoring device for optimizing exercise dosage for a user includes a housing. A strap that is coupled to the housing defines a loop that is configured to insert a wrist of a user to couple the housing to the wrist. A first sensor and a second sensor, which are coupled to a lower face of the housing, are configured to contact the wrist of the user. The first sensor and the second sensor are optical type and thus configured to emit light and to measure reflected light to determine a heart rate and blood pressure of the user, respectively, to estimate a fitness state of the user. A screen that is coupled to an upper face of the housing is configured to display to the user the heart rate, the blood pressure, and at least one of an exercise dosage, an exercise recommendation, and the fitness state.

The present application relates generally to computer software, mobile electronics, wireless communication links, and wearable monitoring systems. More specifically, techniques, systems, sensors, circuitry, algorithms and methods for wearable monitoring devices and associated exercise apparatus are described. A garment borne sensor system may acquire data on a user's performance during exercise, for example. The data may be analyzed in real time and feedback may be provided to the user based on the analysis. Analysis may be used to alter behavior of the user and/or an apparatus the user is engaged with during an activity, such as exercise, conditioning, therapy, etc. A piece of exercise equipment may be instrumented and in communication with the sensor system or other system and may be controlled in real time to adjust its settings to affect the user during the exercise routine. Communication between the sensor system and other systems may be wireless.