A system for controlling a clock device is provided. The system includes a clock device in communication with a remote computing device. The remote device is configured to adjust the time of a countdown and define an adjusted time value. The remote device communicates the adjusted time to the clock device, which automatically displays the adjusted time on a screen. The adjusted time is further communicated to a cloud server via API. The adjusted time is accessible by authorized third parties for display or broadcast. Accordingly, a user may adjust and track a countdown and may define an official time that is automatically displayed to a variety of end-users in real-time. The clock device may be positioned adjacent a competition area and may include a rigid metal frame and a flexible LED screen extending around the perimeter of the frame. The clock device may include hardware and software for processing and outputting the adjusted time to the cloud server.

A system for controlling a clock device is provided. The system includes a clock device in communication with a remote computing device. The remote device is configured to adjust the time of a countdown and define an adjusted time value. The remote device communicates the adjusted time to the clock device, which automatically displays the adjusted time on a screen. The adjusted time is further communicated to a cloud server via API. The adjusted time is accessible by authorized third parties for display or broadcast. Accordingly, a user may adjust and track a countdown and may define an official time that is automatically displayed to a variety of end-users in real-time. The clock device may be positioned adjacent a competition area and may include a rigid metal frame and a flexible LED screen extending around the perimeter of the frame. The clock device may include hardware and software for processing and outputting the adjusted time to the cloud server.

The method for timing a basketball match is defined by a timing system, which comprises a timing device linked to an optical ball detector and/or linked to at least one visual ball detector for detecting a ball in a basketball hoop. The optical ball detector comprises an optical sensor positioned near or on the basketball hoop, and the visual detector comprises at least one kinetic camera for detecting the motion and the depth of the ball in the basketball hoop with processing of the signal. The method comprises the steps of starting to count game time by activating the timing device, of capturing, using the optical sensor and/or the kinetic camera, the passage of the basketball ball into a rim of the basketball hoop, and of transmitting at least one signal detecting the passage of the ball into the basketball hoop to the timing device in order to stop game time.

Mesh networks of radio node pods for measuring performance of teams and individual athletes by first stimulating and then by measuring a parameter of motion selected from velocity, vector, acceleration, force, and rebound. The system includes one or more radio node pods, each radio node pod having a microprocessor, supporting circuitry, a machine layer with one or more sensors and actuators, firmware for essential functions, and a soft socket for receiving codelets on the fly, each codelet containing a soft mini-script and attendant variables for iteration of a stimulus-response-sequence (SRS) customized to a previous iteration or training goal. Radio node pods may work in clusters and are typically multipotent, each pod performing specialized functions as dictated by a resident codelet but otherwise all pods having the same or similar hardware. Shared resources, either internal or external to the mesh network, are used for data analysis. Thus a single pod may trigger a stimulus to a user, and another pod may record a response, but are interchangeable, and each response may be a stimulus to trigger another SRS. Communications with an external administrative network or cloud host is generally delegated to a bridge pod dedicated as a gateway or portal. Each individual subject or team is assessed for performance metrics by which a stimulus results in a qualitative or parametric response. According to current best practice, radio pod nodes are synchronized in each mesh network and wirelessly report raw data and/or derived data to an administrative module for reporting, display and recordation. Relative performance of individuals or teams can be tracked or trended to detect weaknesses and improve workout, sports, military training performance, and contests can also be scored using these systems.

The auxiliary shot clock is used during a basketball game. The auxiliary shot clock is a timing device that: 1) operates a five-second timing device that detects a five-second violation for an inbound pass; 2) operates a ten-second timing device that detects a half court violation after an inbound pass; 3) displays the time of the five-second timing device; 4) displays the time of the ten-second timing device; 5) generates an alarm signal on expiration of the five-second timing device; and, 6) generates an alarm signal on expiration of the ten-second timing device. The auxiliary shot clock comprises a five-second timing device, a ten-second timing device, one or more time lapse displays, and a plurality of control signals. The five-second timing device, the ten-second timing device, and the one or more time lapse displays are electrically interconnected using the plurality of control signals.

The auxiliary shot clock is used during a basketball game. The auxiliary shot clock is a timing device that: 1) operates a five-second timing device that detects a five-second violation for an inbound pass; 2) operates a ten-second timing device that detects a half court violation after an inbound pass; 3) displays the time of the five-second timing device; 4) displays the time of the ten-second timing device; 5) generates an alarm signal on expiration of the five-second timing device; and, 6) generates an alarm signal on expiration of the ten-second timing device. The auxiliary shot clock comprises a five-second timing device, a ten-second timing device, one or more time lapse displays, and a plurality of control signals. The five-second timing device, the ten-second timing device, and the one or more time lapse displays are electrically interconnected using the plurality of control signals.

A sports event time clock control system utilizing remotely activated game clock controls in which the sonic fingerprints including multiple harmonic frequencies of each official's whistle blow is compared with prerecorded sonic fingerprints of the officials for activation of the game clock upon a match in sonic fingerprints and to identify and record the official who blew the whistle along with the strength if the whistle blow. Sonic fingerprints include the strongest harmonic plus selected strong overtone and undertone frequencies.

A sports event time clock control system utilizing remotely activated game clock controls in which the sonic fingerprints including multiple harmonic frequencies of each official's whistle blow is compared with prerecorded sonic fingerprints of the officials for activation of the game clock upon a match in sonic fingerprints and to identify and record the official who blew the whistle along with the strength if the whistle blow. Sonic fingerprints include the strongest harmonic plus selected strong overtone and undertone frequencies.

A clock device is in communication with a remote computing device that is configured to adjust the time of a countdown and define an adjusted time value. The remote device communicates the adjusted time to the clock device, which automatically displays the adjusted time on a screen. The adjusted time is further communicated to a cloud server via API. The adjusted time is accessible by authorized third parties for display or broadcast. Accordingly, a user may adjust and track a countdown and may define an official time that is automatically displayed to a variety of end-users in real-time. The clock device may be positioned adjacent a competition area and may include a rigid metal frame and a flexible LED screen extending around the perimeter of the frame. The clock device may include hardware and software for processing and outputting the adjusted time to the cloud server.

A clock device is in communication with a remote computing device that is configured to adjust the time of a countdown and define an adjusted time value. The remote device communicates the adjusted time to the clock device, which automatically displays the adjusted time on a screen. The adjusted time is further communicated to a cloud server via API. The adjusted time is accessible by authorized third parties for display or broadcast. Accordingly, a user may adjust and track a countdown and may define an official time that is automatically displayed to a variety of end-users in real-time. The clock device may be positioned adjacent a competition area and may include a rigid metal frame and a flexible LED screen extending around the perimeter of the frame. The clock device may include hardware and software for processing and outputting the adjusted time to the cloud server.