Adaptive basketball shooting devices are disclosed that allow a person with limited use of his or her arms to shoot a basket from a seated position in a wheelchair. In preferred implementations, the device allows a person with limited mobility to pick up, carry, and shoot a basketball. Some devices include a frame, a conveyor configured to retrieve a ball from a surface on which the wheelchair is positioned, e.g., a floor or a paved basketball court, and in cooperation with the frame convey the ball vertically relative to the frame, and a driven wheel mounted on the frame and configured to eject the ball upward from the device.

A basketball training apparatus includes a shot completion sensor, a condition sensor, and a computer. The shot completion sensor determines whether a shot goes through a basketball hoop. The condition sensor senses a physical condition of a basketball shooter. The computer is in communication with the shot completion sensor and the condition sensor, and has a processor for calculating shot completion percentage as a function of the physical condition.

A method can include providing an object having a size smaller than a size of a known regulation object, projecting the object, via a delivery device, toward a trainee, and training the trainee to follow the object. A method can include determining a game parameter of a game trajectory of a sports object that was projected along the game trajectory in a real-time sports event, and based on the game parameters, adapting a delivery device to deliver a training object along a training trajectory that mimics at least a portion of the game trajectory, with the training object being smaller than the sports object.

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.

An exercise apparatus that includes a handle frame and a base frame.

A training system includes a riding plate, a load sensor, a first center of gravity calculation unit, an image-capturing unit, a second center of gravity estimation unit, and a determination unit. The load sensor detects a load that the riding plate receives from a trainee. The first center of gravity calculation unit calculates a first center of gravity, which is a center of gravity of a load, based on the load detected by the load sensor. The image-capturing unit acquires image data of an image including a posture of the trainee. The second center of gravity estimation unit estimates a second center of gravity, which is a centroid position of the trainee, based on the image data. The determination unit determines that an alert to the trainee should be output based on a difference between the first center of gravity and the second center of gravity.

A smart soccer goal for tracking and communicating motion of objects includes a goal frame; a net coupled to the goal frame including a plurality of lights; and one or more sensors coupled to the goal frame. A first sensor of the one or more sensors is directed to detecting movement within and immediately near the smart soccer goal and a second sensor of the one or more sensors is directed to detecting movement outside of the smart soccer goal.

A training system includes a launching device house a computer electrically connected to a mechanical hopper and a plunger disposed within a casing sized to launch a lacrosse ball. The casing is structured and arranged to be movably connected to the housing such that at least one of a launch angle, speed, direction, distance and spin can all be selectively chosen by a user. At least one sensor is designed to be placed onto at least one of a player, the lacrosse ball, or a lacrosse net such that the sensors are structured and arranged to relay metric data to the computer in connection with a training program software operating on the computer, wherein the sensor(s) are wirelessly connected to the computer. A mobile device software application communicates with the computer for tracking the metric data and selective programming of the lacrosse ball tossing and training system by the player.

A basketball training system includes a server computer and a basketball training machine. The server computer executes a workout module that manages operation of a graphical user interface that presents a graphical representation of a portion of a basketball court and receives user inputs that define a workout program that includes selected ball delivery locations relative to the visual representation. The basketball training machine receives the workout program and delivers basketballs to the selected ball delivery locations.

A sports ball throwing machine lift (SBTML) includes a first machine upright post and a second machine upright post that are configured to attach to a sports ball throwing machine. The SBTML further comprises a rod connected vertically between the first machine upright post and the second machine upright post. The SBTML further comprises a base, a plurality of wheels attached to a lower surface of the base, and an upright post that extends up from the base. The SBTML further comprises a lifting bar that is pivotably connected to an upper portion of the upright post. The SBTML further comprises a lifting device configured to cause the lifting bar to lift the rod. The lifting device includes a mechanical jack or an electric actuator.