The present invention is disclosing a performance improvement system comprising a smart athletic flexible accessory and an electronic device communicably coupled with smart athletic flexible accessory. Smart athletic flexible accessory comprises a plurality of fabric sensors configured to measure data associated with a physical activity performed by a user and a first transceiver configured to transmit measured data. Electronic device comprises a second transceiver configured to receive measured data from smart athletic flexible accessory, and a microprocessor. Microprocessor is configured to analyze received data from receiver, generate a recommendation based on analyzed data, and cause a display screen to display generated recommendation.

A smart ball-machine uses artificial intelligence to train a player or to play with a player. For example, the ball-machine can adjust the tennis ball speed, topspin, bounce according to the player's successful ball return rate. The ball-machine can be preconfigured with a profile of a player. For example, the ball-machine may download a complete profile of a tennis player from a game recording, or may download a file with a customized profile of a player to train a player using the ball-machine. The ball-machine is equipped with a plurality of wheels, motors, and shafts to provide a fully customizable launch of one or more balls. For example, the ball can be launched from the machine from one side of a tennis court to another side of a tennis court with a variety of speeds, trajectories, topspin, bounce etc.

Provided herein is a mechatronic simulator system that provides various types of unexpected perturbations to challenge the proactive and reactive balance control in subjects to thereby improve balance control of the subject. The system includes a motion capture unit and a processing unit capable of analyzing the subject’s response to the perturbations, provide real time feedback, adjust and/or determine training sessions.

The present disclosure discloses a calibration method for output force of strength-type intelligent fitness equipment, which belongs to the field of intelligent fitness, including: connecting a tension detection device to the strength-type intelligent fitness equipment; obtaining an actual tension of the strength-type intelligent fitness equipment by turning on the tension detection device to perform detection; obtaining a tension deviation based on a target tension of the strength-type intelligent fitness equipment and the actual tension; and calibrating the strength-type intelligent fitness equipment based on the tension deviation.

The disclosure discloses a compensation method for output force of a strength-type intelligent fitness equipment, which relates to the field of intelligent fitness. The method comprises: obtaining the actual output force of the strength-type intelligent fitness equipment; obtaining the friction force of strength-type intelligent fitness equipment; compensating the output force of the strength-type intelligent fitness equipment based on the actual output force and the friction force.

In response to an indication of a transition in a live workout, a synchronization identifier as metadata is embedded in a portion of a video stream of the live workout. The portion of the video stream of the live workout is transmitted to a remote client exercise machine. A hardware state of the remote client exercise machine is updated based at least in part on the synchronization identifier, at least in part to synchronize the remote client exercise machine with the live workout.

In response to an exercise machine joining a video stream of a live workout, a timeline comprising a set of events that are to occur over the course of the live workout is received. A portion of the video stream of the live workout is received, wherein the portion of the video stream has embedded a synchronization identifier. The portion of the video stream is rendered. A hardware state of the exercise machine is updated at least in part by evaluating the timeline using the synchronization identifier embedded in the portion of the video stream, at least in part to synchronize the exercise machine with the live workout.

An occurrence of a workout event with respect to one or more participants of a live workout is received. A prioritization of the event is determined based at least in part on at least one of a recency of the event or a categorization of the event. The event and the corresponding prioritization to a client exercise machine is transmitted, wherein a position of a presentation of the event on a feed of events on the client exercise machine is based at least in part on the prioritization of the event.

An exercise apparatus includes flexible elongated members configured for attachment to shoes of a user. Motor assemblies are disposed between the elongated members and the shoes, respectively, and cause the flexible elongated members to oscillate. Rotational drums attached to the flexible elongated members and are configured to rotate the flexible elongated members while the elongated members oscillate.

A robotic collection system includes: a working robot configured to autonomously travel on a field to collect target objects on the field; and a management controller configured to manage a work schedule of the working robot. The management controller includes a processor. The processor obtains information about an amount of the target objects on the field, and changes an existing work schedule based on the information.

A safety signal is sent to a relay coupled to a plurality of power leads of a motor wherein a default state of the relay is to short the plurality of power leads together and wherein the safety signal maintains the relay in an open state. The safety signal to the relay is deasserted in response to a determination that an unsafe condition has occurred.

An exercise apparatus includes a motor, an operating member driven by the motor, a sensor operable to detect engagement of a user with the operating member, and a controller in communication with the operating member and the sensor. The controller is configured to generate exercise use data when the operating member is driven by the motor. A communication interface is in communication with the controller. In response to the controller determining that the user is engaged with the operating member, the controller is configured to report the exercise use data to the communication interface. In response to the controller determining that the user is not engaged with the operating member, the controller is configured to stop reporting the exercise use data to the communication interface. The communication interface is configured to communicate the reported exercise use data to a third party.