A shooting simulation system and method. The system includes a plurality of firearms. Each firearm is associated with a separate soldier having a man-worn computer, a location device for determining a location of the soldier, an optical system for capturing an image where the captured image provides information on a trajectory of a virtual bullet fired from a shooting firearm, and an orientation device for obtaining the orientation of the firearm when shooting the firearm. The optical system is aligned with a sight of the shooting firearm and captures the image when shooting the firearm. The system also includes a shooter/target location resolution module for identifying a valid target and a target image recognition module for determining an impact location where a virtual bullet from the shooting firearm would impact within the captured image and determining if an identified target from the captured image is a hit or a miss.

The present disclosure relates to simulated hunting devices and methods, and in particular to an accessory for a real or toy firearm that provides a simulated hunting experience in a real hunting environment. A hunting simulation accessory can be attached to a real or toy firearm, such as by attaching the accessory to an accessory rail along the barrel of the firearm. The simulation accessory provides audio and visual responses to the user to simulate a hunting experience, even when no live ammunition is fired.

A device for simulation of the mechanical functions of a real weapon using electronic and mechanical solutions is described. The simulation device can be mounted on a real weapon.

A device for simulation of the mechanical functions of a real weapon using electronic and mechanical solutions is described. The simulation device can be mounted on a real weapon.

The present invention relates to a shooting system using a drone, and disclosed is a shooting system using a drone, which comprises a laser gun and a sensor capable of receiving laser light instead of a shotgun and a pigeon used in a conventional clay shooting, wherein the laser gun comprises a firing recoil unit and a firing sound unit and the takeoff/landing and flight trajectory of the drone are controlled on the ground, thereby maintaining the advantages of clay shooting while eliminating risk factors related to the use of a shotgun and improving the problems of treating a damaged pigeon.

A shooting simulation system and method. The system includes a plurality of firearms. Each firearm is associated with a separate soldier having a man-worn computer, a location device for determining a location of the soldier, an optical system for capturing an image where the captured image provides information on a trajectory of a virtual bullet fired from a shooting firearm, and an orientation device for obtaining the orientation of the firearm when shooting the firearm. The optical system is aligned with a sight of the shooting firearm and captures the image when shooting the firearm. The system also includes a shooter/target location resolution module for identifying a valid target and a target image recognition module for determining an impact location where a virtual bullet from the shooting firearm would impact within the captured image and determining if an identified target from the captured image is a hit or a miss.

The present disclosure relates to simulated hunting devices and methods, and in particular to an accessory for a real or toy firearm that provides a simulated hunting experience in a real hunting environment. A hunting simulation accessory can be attached to a real or toy firearm, such as by attaching the accessory to an accessory rail along the barrel of the firearm. The simulation accessory provides audio and visual responses to the user to simulate a hunting experience, even when no live ammunition is fired.

The present disclosure relates to simulated hunting devices and methods, and in particular to an accessory for a real or toy firearm that provides a simulated hunting experience in a real hunting environment. A hunting simulation accessory can be attached to a real or toy firearm, such as by attaching the accessory to an accessory rail along the barrel of the firearm. The simulation accessory provides audio and visual responses to the user to simulate a hunting experience, even when no live ammunition is fired.

A firing simulation scope, for installation on a rifle, includes an inertial measurement unit, a windage correction adjustment device, an electronic system, a microphone, a display and an interface for connection to a control station. The electronic system is configured for: receiving, via the connection interface, video data representing a field of view, through a simulated scope, in the virtual environment; displaying on the display the received video data; obtaining a real time audio microphone recording; comparing the audio recording with a predetermined firing-triggering signature of the rifle; and transmitting, to the control station via the connection interface, when the audio recording matches the predetermined signature, a firing triggering detection signal associated with inertial measurements supplied by the first inertial measurement unit and with a first adjustment setting supplied by the windage correction adjustment device, to enable the control station to determine a firing trajectory in the virtual environment.

A firing simulation scope, for installation on a rifle, includes an inertial measurement unit, a windage correction adjustment device, an electronic system, a microphone, a display and an interface for connection to a control station. The electronic system is configured for: receiving, via the connection interface, video data representing a field of view, through a simulated scope, in the virtual environment; displaying on the display the received video data; obtaining a real time audio microphone recording; comparing the audio recording with a predetermined firing-triggering signature of the rifle; and transmitting, to the control station via the connection interface, when the audio recording matches the predetermined signature, a firing triggering detection signal associated with inertial measurements supplied by the first inertial measurement unit and with a first adjustment setting supplied by the windage correction adjustment device, to enable the control station to determine a firing trajectory in the virtual environment.