An apparatus for natural torso and limbs tracking and feedback for electronic interaction with fall safety support. The apparatus comprises a body harness worn on the body of a user, a support structure designed to bear the weight of the user in the event of a stumble, trip, or fall, and a plurality of tethers attached at one end to the harness and at the other end to the support structure. One or more sensors are integrated into the system to measure aspects of the user's movement and used as input to control a computer system. In the event of stumble, trip, or fall, all of, or a portion of, the user's body weight is borne by the tethers as a safety mechanism to prevent injury. The system is designed to be used with virtual reality systems wherein the user's vision is blocked or obscured by a virtual reality visor.

An Internet of Thing (IoT) device includes a camera coupled to a processor; and a wireless transceiver coupled to the processor. Blockchain smart contracts can be used with the device to facilitate secure operation.

Apparatuses that each include at least one body and are configured to move relative to an entrance of goal to form an obstruction. The apparatuses either operate autonomously or have a remote operator and their bodies can be moved in coordination with players, pucks, balls or other object of interest. The apparatuses also each include a removably attachable actuating support. The actuating supports of each are mechanically linked to the body, removably attachable to goals, and in operable communication either a teleoperator or autonomous controller.

A method of varying a dynamic resistive force during a strength training exercise includes receiving a selection of the strength training exercise from a set of available strength training exercises and obtaining exercise logic for the strength training exercise from computer memory. The exercise logic provides instructions for generating a vector that defines the dynamic resistive force provided at an end effector of a strength training apparatus during the strength training exercise. The method includes determining a real-time geometric arrangement of a plurality of cables coupled to the end effector, generating, based on the real-time geometric arrangement of the plurality of cables and the exercise logic, time-varying operating setpoints for a plurality of actuator assemblies coupled to the plurality of cables, and exerting the dynamic resistive force at the end effector by controlling the plurality of actuator assemblies in accordance with the time-varying operating setpoints.

A motion analyzer for attachment to sports equipment. The motion analyzer may be constructed as one unitary piece and may include a base portion and an upper portion. The motion analyzer may collect and record motion data associated with movement of the sports equipment. The motion data may then be communicated to a mobile application which provides a user with a visual representation of the motion of the sports equipment. Further, a method of manufacturing a motion analyzer for attachment to sports equipment.

A sports training device includes a glove with a main body. The main body has a palm portion and a back portion. The main body is configured to receive a hand of a user. A plurality of finger receptacles is disposed on the main body. Each finger receptacle of the plurality of finger receptacles has a proximal end disposed adjacent to the main body and a distal end disposed opposite the proximal end. The plurality of finger receptacles includes a thumb receptacle, a first finger receptacle, and a second finger receptacle. Each of the distal end of the thumb receptacle, the distal end of the first finger receptacle, and the distal end of the second finger receptacle are open. A sensor is disposed on the glove and is configured to monitor a release of an object to be thrown.

An exercise monitor and method thereof having: a displacement sensor; a processing unit having a processor, clock, a memory storage device, and instructions for (1) computing a bounce rate using only displacement data and time data, (2) computing upper and lower displacement thresholds using only displacement data, and (3) for computing intensity using only bounce rate (beat frequency) and upper and. lower displacement thresholds. There is a display unit and a wireless connection to a handheld device on which computed information is displayed. Such automatically monitors workout intensity by receiving displacement data from a single displacement sensor and calculating upper and lower displacement thresholds to use to determine both heat frequency and intensity per beat via which intensity over a period may be displayed to a user.

A system and method for using a body joystick to interact with a virtual or mixed-reality machines or software applications that uses a support arm to hold a device for attaching the body joystick to a user's body, a sensor for detecting movement, and a tether and actuator for providing feedback to the user about interactions with the virtual or mixed-reality machines or software applications.

A captured video image obtaining unit 70 obtains a captured video image in which a player making a golf swing is captured. A club head path specifying unit 82 specifies a path of a club head captured in a captured video image based on the captured video image. A launch direction specifying unit 84 specifies a launch direction of a ball captured in a captured video image based on the captured video image. A curve direction determining unit 88 determines a curve direction of the launched ball based on the path of the club head and the launch direction.

The present invention discloses a cycling or motorcycling simulator for recreation and physical exercise characterized by allowing left, right, and backward movements and tilts that can be controlled with the handlebars or body thrust. Structurally, the device of the present invention is divided mainly into six parts interconnected to get the device to function optimally. Thus, the simulator consists of i) a base that supports the other systems of the invention, ii) a mounting base that allows coupling the lifting system, the lower coupling system, and the lateral tilt system, iii) a frame giving a bicycle-shaped structure to the simulator, iv) a lifting system, v) a lateral tilt system, and vi) a lower coupling system; wherein the said systems control the turns and the tilt of the simulator. Because the present invention allows a greater range and variety of movements, the monotony of the exercise is reduced, and the user can exercise a greater number of muscles.