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. Furthermore, the system includes an aerial drone having a camera to capture a second image. 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 images and determining if an identified target from the captured images is a hit or a miss.

Synthetic training interface devices, methods, and systems. A synthetic training device includes a processor, a communications interface in communication with the processor, a measurement device in communication with the processor, and an input device disposed on a live training device and configured to receive input from a user. Calibration information is captured. The calibration information includes orientation, position, inertial, and/or geometric information regarding the synthetic training interface device, a live training device coupled to the synthetic training interface device, the user, and/or a synthetic training environment. The calibration information is captured via a measurement device and/or user input.

Synthetic training interface devices, methods, and systems. A synthetic training device includes a processor, a communications interface in communication with the processor, a measurement device in communication with the processor, and an input device disposed on a live training device and configured to receive input from a user. Calibration information is captured. The calibration information includes orientation, position, inertial, and/or geometric information regarding the synthetic training interface device, a live training device coupled to the synthetic training interface device, the user, and/or a synthetic training environment. The calibration information is captured via a measurement device and/or user input.

A multi-function dry fire training device to be inserted into the chamber of a firearm, which comprises an illuminator for emitting, upon receiving a command from a controller, a beam of visible or invisible illumination from the barrel of the firearm, the beam being parallel to its central axis; a controller for controlling the functionality of the device including illumination of the illuminator, in response to activation of the firearm trigger; an actuator, being electrically connected to the controller, for activating the controller whenever being struck by the firearm striker and a power source for providing DC power to the controller and illuminator.

A toy gun and a toy gun assembly are provided. The toy gun includes a gun body; a first power supply, a first printed circuit board (PCB), an infrared emitter, a first infrared receiver, a first vibration motor, a trigger, a first display module and a first speaker are arranged in the gun body; the gun body has a gun body portion and a handle portion; the first vibration motor corresponds to the handle portion; and the first display module is exposed from an outer side of the gun body and is disposed towards the upper rear side in a displaying manner.

An apparatus includes a bolt carrier assembly and a bolt assembly. The bolt assembly includes a bolt body member, the bolt body member having a proximal end portion and a distal end portion, and defining a longitudinal axis extending from the proximal end to the distal end. The bolt assembly includes a guide member attached to proximal end portion and the guide member is parallel to the longitudinal axis. The bolt assembly further includes a bolt chamber interface attached to a distal end portion, the bolt chamber interface nests within an interior wall of a firearm chamber, and the bolt chamber interface limits rotational and axial movement of the bolt assembly relative to the firearm chamber. The bolt assembly includes a bolt nipple connector for mating with a nipple assembly of a magazine assembly.

A device can include one or more sensors configured to output sensor data, and a trigger detection module configured to receive the sensor data from the one or more sensors and to determine whether a trigger event has occurred. The trigger detection module can be configured to output a trigger detection signal when the trigger event is detected. The trigger detection signal can be configured to be used by an augmented reality or virtual reality system to cause an augmented reality or virtual reality event.

A device can include one or more sensors configured to output sensor data, and a trigger detection module configured to receive the sensor data from the one or more sensors and to determine whether a trigger event has occurred. The trigger detection module can be configured to output a trigger detection signal when the trigger event is detected. The trigger detection signal can be configured to be used by an augmented reality or virtual reality system to cause an augmented reality or virtual reality event.

A firearm training system includes a firearm, a sensor, a data processor, and a display. The sensor measures and records the motion of the firearm before, during, and after the firearm is shot. In some embodiments, the sensor is located on the firearm. The sensor communicates with the data processor. In some instances this communication is conducted wirelessly. Data regarding the movement of the firearm is analyzed via the data processor and trends are determined. These trends are then correlated with shooting technique deficiencies which can be communicated to a user via the display. In some embodiments, the data processor and display are a single computing device, such as a tablet, smartphone, or laptop.

A firearm training system includes a firearm, a sensor, a data processor, and a display. The sensor measures and records the motion of the firearm before, during, and after the firearm is shot. In some embodiments, the sensor is located on the firearm. The sensor communicates with the data processor. In some instances this communication is conducted wirelessly. Data regarding the movement of the firearm is analyzed via the data processor and trends are determined. These trends are then correlated with shooting technique deficiencies which can be communicated to a user via the display. In some embodiments, the data processor and display are a single computing device, such as a tablet, smartphone, or laptop.