An exercise method and an exercise equipment are provided. The exercise method includes: determining an exercise guiding video according to a selected music input/audio signal, wherein the exercise guiding video includes a first exercise guiding video and/or a second exercise guiding video, the first exercise guiding video is a live video automatically generated according to the selected music input/audio signal, the second exercise guiding video is a video previously recorded according to the selected music input/audio signal; generating CGA and special-effect/animated feedbacks corresponding to the music information/audio signal and instruction/cuing in the exercise guiding video; playing the exercise guiding video, the CGA, the special-effect/animated feedbacks and the selected music input/audio signal on a display and computing device; receiving user performance data; displaying interactive feedback data on the display and computing device, according to a result obtained by matching the user performance data with music information/audio signal analyzed from selected music input/audio signal.

A system for exercise assessment and prescription generation, which is signally connected with at least one exercise device includes a biological information collecting module, an assessing standard generating module, an exercising information collecting module and a personal prescription generating module. The biological information collecting module collects biological information of a user. The assessing standard generating module is signally connected with the biological information collecting module and a cloud data platform, and for generating an assessing standard by calculating the biological information and the plurality of reference information in the cloud data platform. The exercising information collecting module is signally connected with at least one exercise device, and obtains assessed exercising information.

An exercise bike and a handlebar assembly are provided. The handlebar assembly includes: a rod-shaped handlebar; a support post; a first connecting component comprising a first recess, and further comprising a first tenon and a second tenon; a second connecting component comprising a first side, a second side away from the first side and a sidewall connecting the first side to the second side, wherein the second side of the second connecting component is provided with a second recess, and further provided with a first mortise and a second mortise. When the second recess is aligned with the first recess, a first through-hole is formed for the handlebar passing through, the first tenon is inserted in the first mortise, and the second tenon is inserted in the second mortise. The handlebar assembly can be easily assembled to the exercise bike.

Systems and methods for electronically creating and modifying a fitness plan are disclosed. The method may include receiving electronic user data, collecting electronic fitness data, and displaying a suggestion for a fitness activity based on the electronic user data and the electronic fitness data.

An exercise device comprises a rigid rod having a first and second ends, a plurality of light sources arranged in a row along at least a portion of an axis extending between the first and second ends of the rigid rod, at least one load sensor for detecting an applied longitudinal force, and a processor coupled to the at least one load sensor and to the plurality of light sources. The processor is configured to execute machine-executable instructions that cause the processor to obtain a signal indicating a magnitude of the applied longitudinal force, and cause a subset of the plurality of light sources to emit light. A ratio of a number of light sources in the subset to a total number of the plurality of light sources represents the magnitude of the applied longitudinal force relative to a reference longitudinal force.

Athletic performance monitoring systems and methods, many of which utilize, in some manner, global positioning satellite (“GPS”) data, provide data and information to athletes and/or to equipment used by athletes during an athletic event. Such systems and methods may provide route information to athletes and/or their trainers, e.g., for pre-event planning, goal setting, and calibration purposes. Such systems and methods optionally may provide real time information to the athlete while the event takes place, e.g., to assist in reaching the pre-set goals. Additionally, data and information collected by such systems and methods may assist in post-event analysis for athletes and their trainers, e.g., to evaluate past performances and to assist in improving future performances.

Systems, methods and computer readable media comprising a virtual exercise board, which is represented by images on the screen of a pad device; wearable devices configured to attach to each shoe of a user and to collect and transmit touch data to the pad device; cameras for tracking movement and calibrating with the data collected by the wearable devices; and computer programs for collecting user data, processing user data, and generating outputs. In embodiments, features include augmented reality; ratings of performance; automated workouts/protocols; real-time progress bar; multi-location database capabilities; and reports.

A method and apparatus for recommending a route. The route recommending method includes obtaining user's current body information; obtaining geographic information from a current position to a destination; and determining a recommended route to the destination on the basis of the body information and the geographic information.

An Internet of Thing (IoT) sport device includes a body with a processor, a camera and a wireless transceiver coupled to the processor.

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.