A sports ball, for example a soccer ball, comprising a hollow shell and a pit suspended within the hollow shell by a plurality of cords. In some embodiments, the plurality of cords may comprise a first end coupled to the hollow shell at a first location, a second end coupled to the hollow shell at a second location, and a center portion coupled to the pit. In some embodiments, the pit may be suspended within the hollow shell by a plurality of cords, with each of the plurality of cords comprising a frayed end secured to the hollow shell at one of a plurality of spaced apart locations.

A smart ball (100) comprising: an inner sphere portion (12) consisting of a cork like material and an outer sphere (19) that ensconces said inner sphere, said inner sphere further comprising: a cylindrical cavity (14), located substantially at the core of said ball, said cavity formed by drilling into said cork from an operative top side; a sensor assembly (16) placed in the centre of said cylindrical cavity along a reference plane defined by a locus of points wherein said points being collinear points running from a first end of said seam (18) to a second end of said seam, thereby ensuring that orthogonal measurements of said sensor assembly being aligned with orthogonal axes of said ball; and a charging port on said seam, said charging port connected to a battery placed in said cylindrical cavity and said battery connected to said sensor assembly.

An intelligent sports equipment system and method for processing data as a result of different types of events associated with a puck or ball and generally another piece of sports equipment. The information associated with each type of event can include associating player information with the processed data. In one example a smart hockey puck has embedded electronics for sensing motion across a plurality of axes, a hockey stick has an associated RFID tag that can be read by the smart hockey puck, which can transmit information to a computing device for displaying processed data.

An intelligent sports equipment system and method for processing data as a result of different types of events associated with a puck or ball and generally another piece of sports equipment. The information associated with each type of event can include associating player information with the processed data. In one example a smart hockey puck has embedded electronics for sensing motion across a plurality of axes, a hockey stick has an associated RFID tag that can be read by the smart hockey puck, which can transmit information to a computing device for displaying processed data.

A sports ball includes sensing electronics embedded therein. The electronics are supported on an inner surface of the wall of the ball within an elastomeric boot that extends inwardly toward the center of the ball. The elastomeric boot is configured to protect the electronics from damage due to shock as the ball is used, and to have little if any effect on the performance characteristics of the ball.

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

A luminous ball with remote activation capability includes a sphere, a cover and a light-emitting device. The cover wraps an external circumferential surface of the sphere and is made of a light-transmissive material. At least one seam is formed on the cover, and a plurality of seam apertures are disposed in pairs along two sides of the at least one seam. The light-emitting device is disposed in the sphere and includes a light-emitting unit, a power unit, a wireless transmitter-receiver unit and a main control unit. The main control unit is operably configured to provide an electrical connection between the light-emitting unit and the power unit after obtaining an activation signal received by the wireless transmitter-receiver unit such that light emitted by the light-emitting unit penetrates the sphere and the cover and is visible through the at least one seam and the plurality of seam apertures.

A multimedia crossbar system for goal posts of different spots. The system includes a goal frame, a net, a rear net frame, a multimedia bar, and a transparent display screen. The goal frame includes a front crossbar, a first post, and a second post to yield a U-shape. The rear net frame holds up the net behind the goal frame and includes a rear crossbar, a first rear post, and a second rear post. The multimedia bar includes a support bar, a plurality of lights, a plurality of speakers, and a plurality of sponsor display panels for audiovisual entertainment around the goal frame. The support bar is mounted to the rear crossbar and support the lights, speakers, and the sponsor display panels. The transparent display screen provides another visual medium for advertisement and other similar content. The transparent display screen is positioned and perimetrically connected within the rear net frame.

Described herein are embodiments of sensorized spherical input and output devices, systems, and methods for capturing gestural input from a user's physical interactions with a spherical device, including tossing, bouncing and spinning. In one embodiment, the spherical input and output device includes force sensors in a configuration to capture a variety of user gestures with the sphere. A microprocessor receives sensor input and transmits the sensor data to receiving devices which include computer software to translate the sensor signals to audio output, visual output, or various functions on receiving devices. Embodiments of the invention include the integration of inertial measurement units (IMUs), which may include a combination of accelerometers, gyroscopes and magnetometers to capture complex user gestures involving motion, direction and spin of the sensorized sphere in three dimensional space.

A ball with a sensor incorporated therein is provided. The ball includes a first sensor including a multiaxial acceleration sensor, a first communication unit for wireless transmission of sensor data detected by the first sensor, and a battery for supplying electric power to the first sensor and the first communication unit. The first sensor includes a first multiaxial acceleration sensor housed at a position intended to be a center of gravity of the ball. Each of the first communication unit and the battery is arranged at a position out of the position intended to be a center of gravity.