A shooting score identifying method and device, and an electronic device are provided. The method includes the steps of capturing a picture of a shooting operation on target paper to acquire a shooting image formed on the target paper; forming a thermal imaging image of the target paper after the shooting image is acquired; performing target identification on the shooting image to obtain a target image related to a shooting point, and performing direction correction on the shooting point present in the target image to obtain a correction image; and performing interference removal processing on the correction image through the thermal imaging image to obtain an identification image, thereby identifying a shooting score based on the identification image.

A shooting score identifying method and device, and an electronic device are provided. The method includes the steps of capturing a picture of a shooting operation on target paper to acquire a shooting image formed on the target paper; forming a thermal imaging image of the target paper after the shooting image is acquired; performing target identification on the shooting image to obtain a target image related to a shooting point, and performing direction correction on the shooting point present in the target image to obtain a correction image; and performing interference removal processing on the correction image through the thermal imaging image to obtain an identification image, thereby identifying a shooting score based on the identification image.

A system trains usage of a firearm and includes an end unit, a processing subsystem, and a control subsystem remotely located from the end unit. The end unit includes an image sensor that is positioned against a target that has a bar code. The image sensor defines a field of view of a scene that includes the target, and the bar code stores encoded information that defines a target coverage zone. The system selectively operates in a first mode and a second mode according to input from the control subsystem. In the first mode the end unit scans the bar code to extract the target coverage zone. In the second mode the image sensor captures a series of images of the target coverage zone, and the processing subsystem analyzes regions of the captured series of images to determine a strike, by a projectile of the firearm, on the target.

A gaming system may include: an infrared signal emitter configured to emit an infrared signal, the infrared emitter being configured to emit a predetermined number of emissions per a simulated reloading action, the infrared signal being configurable to be associated with one of at least a first team, a second team, and a neutral team, the infrared signal emitter including a handle to be grasped by a player and a trigger to effect emission of the infrared signal; and an infrared signal receiver configured to receive the infrared signal associated with one of the at least the first team, the second team, and the neutral team. Optionally, the gaming system may include a stationary receiver and emitter for integrated use with game players in a further modification of the methods and uses herein. The stationary receiver and emitter may receive and transmit signals, store a memory of activities, teams, players, and other game-playing benefits.

A gaming system may include: an infrared signal emitter configured to emit an infrared signal, the infrared emitter being configured to emit a predetermined number of emissions per a simulated reloading action, the infrared signal being configurable to be associated with one of at least a first team, a second team, and a neutral team, the infrared signal emitter including a handle to be grasped by a player and a trigger to effect emission of the infrared signal; and an infrared signal receiver configured to receive the infrared signal associated with one of the at least the first team, the second team, and the neutral team. Optionally, the gaming system may include a stationary receiver and emitter for integrated use with game players in a further modification of the methods and uses herein. The stationary receiver and emitter may receive and transmit signals, store a memory of activities, teams, players, and other game-playing benefits.

A method for calculating a position of a dart pin attached to a dart board divided into a plurality of segments in an apparatus for calculating a position of a dart pin is provided. The method includes obtaining a plurality of optical data from a plurality of optical devices corresponding to at least one of a plurality of holes formed in each segment and installed on the rear surface of the dart board; and calculating a position of a dart pin attached to the dart board using the plurality of optical data.

A method for calculating a position of a dart pin attached to a dart board divided into a plurality of segments in an apparatus for calculating a position of a dart pin is provided. The method includes obtaining a plurality of optical data from a plurality of optical devices corresponding to at least one of a plurality of holes formed in each segment and installed on the rear surface of the dart board; and calculating a position of a dart pin attached to the dart board using the plurality of optical data.

A laser sight device for a firearm is provided with a variable power output. In one example, the laser sight device may include a laser assembly configured to provide a laser beam. The laser sight device may include a sensor configured to provide a sensor signal comprising a motion parameter value associated with motion of the laser sight device detected by the sensor while the laser sight device is attached to the firearm. The laser sight device may include a controller configured to provide a control signal to the laser assembly to selectively adjust an intensity of the laser beam in response to the motion parameter value. Additional features and related methods are also provided.

A laser targeting apparatus rests on a surface and moves, such as by vibrating, wobbling, or shaking, when struck by laser light of sufficient intensity. The apparatus is designed not to fall over, so a user does not have to move to the apparatus and pick it up after a strike. The apparatus has a body that includes a structure, which is preferably one or more printed circuit boards including light sensors, for detecting strikes of laser light, and a motor. When a strike of laser light is detected, power is provided to the motor, which vibrates and causes the apparatus to move.

A synchronized infrared beacon/infrared detector system. The system may include (A) an infrared beacon module configured to generate a time-varying encoded infrared signal, (B) an infrared detector module configured to capture the encoded infrared signal generated by the beacon module, (C) a synchronizer configured to generate a synchronization signal that controls timing of the beacon module and the detector module, and (D) a processor, in communication with the detector module, configured to analyze the infrared signal captured by the detector module. The infrared signal may be modulated at frequencies undetectable by human vision. The synchronizer signal may be produced independent of the capture of, and without input from, the infrared signal.