A training apparatus is disclosed that comprises an obstacle member defining a pass-under area for a sports player to pass a sport-projectile through when in use. The training apparatus comprises a first sensor that is configured to detect the sport-projectile passing through the pass-under area, and a controller that is configured to determine a pass-through direction of the sport-projectile that passes through the pass-under area based on data received from the first sensor. The training apparatus also comprises a lighting fixture indicating an instructed pass-through direction for the sports player to pass the sport-projectile through the pass-under area. A system for training a sports player is described that comprises a plurality of training apparatuses that are remotely configurable to define a training drill for a sports player and to collect training data from execution of the training drill. A method for training a sports player is also disclosed.

The present disclosure is directed to a system for sensor-based objective determination. In general, sensor data may be used to render objective determinations that were not previously possible due to the unavoidable subjectivity of human-based officiating systems. For example, at least one device may be configured to make objective determinations during the course of a sporting event. Data collection circuitry may receive data from sensor devices coupled to players, equipment, playing surfaces, etc. Data analysis circuitry may categorize the data and input the data into a model to determine if an infraction occurred. For example, categorization may involve determining a type of infraction that may have occurred based on the sensor data. The model may then be selected based on the type of infraction, the model being developed utilizing prior sensor data, rules for the sporting event, etc. Output circuitry may generate a notification based on the infraction determination.

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.

A cattle roping training dummy (90) that allows a “header” and a “heeler”' to practice roping the head of the cattle roping training dummy (90), the hind legs (175) of the cattle roping training dummy (90), or a combination of the head and the hind legs (175) is described. The cattle roping training dummy (90) comprises a frame (100), a spring (200), a supporting structure (300) and a base (400). The cattle roping training dummy (90) may further comprise a means to actuate side release lever (500). When the frame (100) is released, the spring (200) gives the frame (100) an initial jerk as the frame (100) and provides rotational motion around the supporting structure (300). This jerking motion mimics a live steer that has been roped on the horns or head and is jerked sideways as the cowboy pulls the steer to the left. The cattle roping training dummy (90) also provides the “heeler” with the opportunity to practice alone. The cattle roping training dummy (90) provides the convenience of: a) quick fold up for easy moving and storing, and b) quick setup.

A soccer training device can include: a body having a front surface facing a first direction; and an illuminating contact sensor associated with the body so that a light emitter is visible and capable of emitting light in substantially the same first direction that the front surface faces and so that a force contact above a predetermined threshold with the body is sensed by a sensing module. In some aspects, the illuminating contact sensor is at least one of: coupled with the soccer training member; removable from the soccer training member; or integrated with the soccer training member.

A computer-implemented system includes an assistant interface for providing remote medical assistance to aid a patient in performing various aspects of a rehabilitation regimen for a body part comprising a joint, a bone, or a muscle group. The assistant interface is configured to communicate, via a network connection, a telemedicine signal with the patient interface. The telemedicine signal is configured to control the patient interface and/or a treatment apparatus configured to be manipulated by the patient to perform the rehabilitation regimen. The patient interface and the treatment apparatus are at a patient location geographically separate from a location of the assistant interface. The telemedicine signal includes one or more of an audio signal, an audiovisual signal, an interface control signal for controlling a function of the patient interface, and/or an apparatus control signal for changing an operating parameter of the treatment apparatus.

A device for visual walking includes an omnidirectional exercise machine and foot wearable devices. A method for visual walking is applied to the device for visual walking. When a user wears the omnidirectional exercise machine and uses the loading frame to adjust a height of the omnidirectional exercise machine, and wears the foot wearable devices to stand and run on a running plate, human body posture data is obtained by tracking a human body torso. Then displacement data of left and right feet is obtained by tracking the feet. A virtual position and a movement speed of the feet are respectively obtained according to the displacement data, the leg posture is inferred by the IK algorithm according to the virtual position and the walking action of the virtual character is controlled according to the human body posture data, the movement speed of the feet, and the leg posture.

Systems and methods for dynamic resistance training are provided that include the use of a dynamic force module. The dynamic force module includes an actuator and controller adapted to control the actuator according to a force profile that specifies the relationship between an operational parameter of the actuator and a measured parameter associated with a user performing an exercise. The dynamic force module is also capable of communicating with a broader network system to facilitate storing and distribution of force profiles and user profile information. The network system further includes features for, among other things, generating and managing force profiles, uploading multimedia content, and tracking user progress.

To provide a highly reliable, cost-effective traveling collector that can determine the positions of fallen objects, such as balls, on the ground using a simple method, or determine the correct positions of fallen objects, such as balls, on the ground only by improving software and without the need for significant changes to hardware. The traveling collector includes a count sensor as a sensor for detecting the position of each collected ball at a position detected by a satellite positioning system, for example. A controller determines a position, which is obtained by reflecting, based on the positional information on the ball collector at a time point when the ball was counted by touching the count sensor, the movement distance of the ball collector from the time each ball was picked up from the ground by a ball collection wheel till the ball was counted by touching the count sensor in a direction opposite to the traveling direction of the ball collector at that time, as the actual position where each ball was picked up.

A capacitive sensing climbing hold includes at least one polymer matrix and an anchor point provided in the polymer matrix, the anchor point being configured for attaching the climbing hold to a climbing wall and for transmitting a capacitive contact to a capacitive sensing unit. The polymer matrix includes a carbon powder so that the carbon powder represents between 5% and 35% of the weight of the polymer matrix, preferably between 10% and 35% of the weight of the polymer matrix, the carbon powder being substantially evenly distributed in the polymer matrix.