An exercise information measurement apparatus 10 includes: a storage control unit 22 that stores a movement pace and bodily information measured during movement of a wearer in association with each other in a storage unit 5; a movement pace allocation setting unit 23 that sets a movement pace allocation for when moving over a designated distance; a movement pace correction unit 25 that corrects the set movement pace allocation based on the movement pace and the bodily information stored in the storage unit 5; and a guide unit 26 that guides a movement pace of the wearer in accordance with the corrected movement pace allocation.

A display board system for football coaching applications is provided. The system enables football coaching staffs to communicate any convey information to on-field players, such as the personnel types of the opposing team or the specific play call for the ensuing play. The system includes a visual display board, a control device, and a control application. The display board includes one or more rows of illuminating numbers that displays any selected set of one or more numerical digits for viewing by the on-field players. The control device is in electronic communication with the display board via wired or wireless connection and is configured for use by the coaching staff to input the desired information for display on the display board. The control application is a programming application configured to run on the control device to enable operation of the control device to display information on the display board.

An exercise accessory includes a load bearing element. It further includes a haptic actuator. In response to an indication of an event pertaining to a load on the load bearing element, the haptic actuator is configured to generate a vibration pattern corresponding to the event. Different events are associated with different vibration patterns.

Bilateral vestibular loss is a chronic condition of which the causes can be ototoxic, infectious, traumatic, autoimmune or congenital. An object of the invention is to improve the effectiveness of a vibrotactile feedback arrangement. The current invention provides a vibrotactile feedback arrangement for use arranged to a human body, comprising: a sensor arranged for sensing a current attitude of the human body relative to the environment; tactile actuators arranged for allowing the human body to perceive an attitude deviation; an elongated carrier for holding the tactile actuators and the sensor in tactile communication with the human body and for holding the tactile actuators and the sensor substantially fixed relative to the human body; and a processing unit configured for: receiving the current attitude from the sensor; determining the attitude deviation based on comparing a desired attitude of the human body with the current attitude; and transmitting an actuation signal to one or more of the tactile actuators based on the attitude deviation; wherein the tactile actuators are arranged to the carrier such that, when the carrier is used, the tactile actuators are arranged substantially in a reference plane; wherein the reference plane is functionally perpendicular to a central axis of a torso of the human body and the reference plane intersects the torso to define a circumference, wherein the tactile actuators are arranged to the circumference; and wherein the carrier comprises stretchable material such that the relative distance between the tactile actuators and/or between the tactile actuators and the sensor is maintained independent of the length of the circumference.

The systems and methods described herein are directed towards collecting and recording sensor data pertaining to physical contact experienced by players in a contact sport (e.g., football). The data can be collected and recorded through the use of one or more sensors worn by the player. In some cases, the sensor data can be associated with in-game video recordings of physical contact experienced by the players. Information about the physical contact can be displayed for users to view via a graphical user interface. Warnings may also be provided.

A mobile exercise device (1) having a plurality of exercise equipment modules (2, 3, 4). Each said module including a frame (7, 8, 9) defining a space (10, 11, 12) adapted to receive exercise equipment. A plurality of mounting means (46) locatable on said frames to connect said modules together. A plurality of indicators (30) operatively associated with said modules and adapted in use to direct a user and/or trainer to the equipment to use for a particular exercise routine.

A device and method for regulating a pace of golf play. A golf course is divided into segments, with each segment assigned a time for completion by a user golfer group. Spaced apart signal lights are positioned on the golf course. Each golfer group is provided with a wireless positioning device. A computing device compares an elapsed time for completion of a number of segments with the total assigned time for the number of segments completed. The computing device wirelessly actuates a visual signal to the golfer group by a signal light on the golf course when the elapsed time for completion of the number of segments by the user golfer group is greater than the total assigned time for the number of segments completed. The device and method take into account impediments to pace of play that are outside of the golfer group's control.

A system for measuring weight-lifting performance is described. The system comprises a collar that may be attached to a weight bar, wherein the collar comprises at least one motion sensor, at least one touch sensor, and a signal processor. The motion sensors comprise a barometric altimeter, a gyroscope, and/or an accelerometer that measure the motion of the weight bar during a lifting activity. Signals from the motion sensors are interpreted by the signal processor as physical activity data, which are then wirelessly transmitted to a multimedia device having a data processor. The data processor is configured to calculate performance metrics from the physical activity data and to display them to a user via a display on the multimedia device. Athletes may use the performance metric outputs from the data processor to monitor the form of their lifting exercises for training purposes, safety considerations, and self-improvement.

Provided is Exercise equipment including a gripping section that is gripped by a user; a weight section that is connected to the gripping section; a first electrode that is arranged on the gripping section; a second electrode that is arranged on the weight section; a measuring section that measures at least one of body fat percentage of the user and an electrocardiogram waveform of the user, using the first electrode and the second electrode.

An adaptive training system can determine a finite work capacity and critical power and use those determinations to generate an adaptive training programs for workout parameters. To determining a finite work capacity and critical power, the adaptive training system can receive workout data; generate data points by determining, for each workout, a maximum amount of work done for each of multiple time window sizes; fit these workout data points to a function; and determine a critical power and finite work capacity based on the fitted function. Once the adaptive training system has determined a critical power and finite work capacity, the adaptive training system can use them to generate an adaptive training program by keeping a function defined by a set of workout parameters below an ability function that is based on the critical power and finite work capacity.