Provided is an analysis apparatus including an acquisition unit that acquires vibration data showing a vibration generated in a first object by having a second object come into contact with a first position on the first object, a first analysis processing unit that specifies the first position by comparing a vibration characteristic shown by the vibration data, and a vibration characteristic defined for each position where the second object may come into contact with the first object, and a second analysis processing unit that estimates a velocity after the contact of the second object based on a velocity of the first object and the first position.

A non-limiting example training instrument comprises a hollow main body formed of an aluminum alloy. The main body is constituted by two gripping portions opposite to each other with a space therebetween and a coupling portion coupling the two gripping portions. A load sensor is arranged in the coupling portion inside the main body. The load sensor is a load cell, a strain gauge affixed to an interior of the main body, and a part of the main body to which the strain gauge is affixed functions as a strain body. Therefore, if a user applies a force so as to bring the two gripping portions close to each other or a force so as to move the two gripping portions away from each other, a load thereof is detected by the load sensor.

It is provided an apparatus for training a person's lower and/or upper extremities, comprising at least two motion elements which are arranged on a base element, wherein the motion elements each have an axis of rotation around which an actuating element can be moved. The motion elements each are independently movable relative to the base element about a first axis of movement, wherein the first axis of movement extends substantially perpendicular to an extension surface of the base element. Each motion element has a separate drive in order to rotate the actuating elements about the axis of rotation, and that the apparatus includes a control element which can individually actuate each drive in order to provide for a movement of each drive independent of a movement of another drive.

A computer-implemented method is disclosed that includes instructing a human player to perform a plurality of different actions in a determined order with a physical basketball, including actions of bouncing the physical basketball, and obtaining, with one or more electronic sensors, data that characterizes motion of the physical basketball being handled by the human player who is performing the instructed actions at a location. The method also includes communicating the data from the sensors to a console videogame system that is proximate to the location, and graphically representing, in a videogame displayed on a display device, performance by the human player, the performance being affected by the captured data, the representation of performance by the human player being compared against a standard of performance.

The present disclosure provides an intelligent insole module. The intelligent insole module is placed inside an insole for tracking a user's exercise behavior. The intelligent insole module comprises a sensing unit, a wireless unit, a control unit and a power supply unit. The sensing unit detects an exercise information. The wireless unit transmits the exercise information. The control unit is connected to the sensing unit and the wireless unit, and controls the sensing unit and the wireless unit. The power supply unit is connected to the control unit, and supplies electricity to the intelligent insole module. The power supply unit comprises a magnetic charging structure.

The disclosure is directed to systems and methods for providing a user with key performance indicators of a basketball player relating to accuracy, precision and improvement. Specifically, the disclosure is directed to a system of sensors coupled to a basketball backboard adapted to provide an accurate tracking of a shot in a given three-dimensional space and extract features manipulated to yield key performance indicators based on establishing whether, how often and where the ball center passes the rim plane at a sub-cm resolution over a period of no more than 200 msec.

Tilt and dynamic terrain simulation systems are provided which are couplable to a wheelchair treadmill and are configured to dynamically tilt the wheelchair during use of the wheelchair treadmill for simulating an uneven terrain condition. In some embodiments, the dynamic tilt system includes one or more elevation devices placed under a platform for tilting the platform of the wheelchair treadmill from a horizontal plane to a non-horizontal plane, and each of the one or more elevation devices is controllably adjustable to extend an adjustable support that is mounted to the platform between a first height and a second height. In some embodiments, each of the one or more elevation devices includes one or more actuators for controllably adjusting a height of the adjustable support between the first height and the second height.

A device includes a signaling means and a motion sensor, and logic for activating or controlling the signaling means in response to a sensed motion according to an embedded logic. The device may be used as a toy, and may be shaped like a play ball or as a handheld unit. It may be powered from a battery, either chargeable from an AC power source directly or contactless by using induction or by converting electrical energy from harvested kinetic energy. The embedded logic may activate or control the signaling means, predictably or randomly, in response to sensed acceleration magnitude or direction, such as sensing the crossing of a preset threshold or sensing the peak value. The visual means may be a numeric display for displaying a value associated with the count of the number of times the threshold has been exceeded or the peak magnitude of the acceleration sensed.

A wearable computing device that is secured or attached to a resilient strap, the resilient strap sized to fit around at least a part of a circumference of a human head. The device has a waterproof storage volume housing a plurality of sensors. The wearable computing device may calculate a plurality of swimming metrics based at least partly on data received from the at least one sensor. The wearable computing device may include a wireless communication subsystem secured to the resilient strap within the waterproof storage volume and may transmit at least one of the calculated plurality of swimming metrics to at least one computing device via the wireless communication subsystem. The wearable computing device may include at least one user output component and may present an indication of at least one of the calculated plurality of swimming metrics at the at least one user output component for communication to the user. The indication may be audio played in an ear piece connected to the strap, or may be visually displayed on a display in an eye goggle portion of the strap.

A training sled configurable for adding weights in some embodiments to increase friction and provide for weight-training by lifting portions of the sled. Sled components are slidably or pivotably connected to permit lifting a shoulder member of the sled to different heights and to achieve an optimal training angle. The training sled having an accelerometer, sensor unit and display for sensing, determining and displaying the force of impact and movement of the training sled.