A firearm that automatically controls the release of bullets, including one or more sensors that provide real-time sensor data of the view in front of the firearm, a computer that identities legitimate targets in the real-time sensor data, without user intervention, a trigger sensor that determines directly or indirectly if the trigger is engaged, wherein as long as the trigger is engaged, the firearm is configured to continuously acquire real-time sensor data, identify legitimate targets and automatically release bullets when the firearm is directed toward the identified targets.

A firing control apparatus and method for installing in a firearm, the apparatus comprising: an energy storing mechanism configured to store mechanical energy which is produced by a mechanical system, upon firing the firearm or by manual operation of the firearm, an electromagnet configured to control the energy storing mechanism, wherein the energy storing mechanism holds or releases the mechanical energy to prevent or enable the firearm from firing, and a processor or an electro-mechanical switch configured to activate or deactivate the electromagnet to control the operation of the energy storing mechanism according to preselected rules.

A firing control apparatus and method for installing in a firearm, the apparatus comprising: an energy storing mechanism configured to store mechanical energy which is produced by a mechanical system, upon firing the firearm or by manual operation of the firearm, an electromagnet configured to control the energy storing mechanism, wherein the energy storing mechanism holds or releases the mechanical energy to prevent or enable the firearm from firing, and a processor or an electro-mechanical switch configured to activate or deactivate the electromagnet to control the operation of the energy storing mechanism according to preselected rules.

A firing control apparatus and method for installing in a firearm, the apparatus comprising: an energy storing mechanism configured to store mechanical energy which is produced by a mechanical system, upon firing the firearm or by manual operation of the firearm, an electromagnet configured to control the energy storing mechanism, wherein the energy storing mechanism holds or releases the mechanical energy to prevent or enable the firearm from firing, and a processor or an electro-mechanical switch configured to activate or deactivate the electromagnet to control the operation of the energy storing mechanism according to preselected rules.

A firing control apparatus and method For installing in a firearm, the apparatus comprising: an energy storing mechanism configured to store mechanical energy which is produced by a mechanical system, upon firing the firearm or by manual operation of the firearm, an electromagnet configured to control the energy storing mechanism, wherein the energy storing mechanism holds or releases the mechanical energy to prevent or enable the firearm from firing, and a processor or an electro-mechanical switch configured to activate or deactivate the electromagnet to control the operation of the energy storing mechanism according to preselected rules.

A firearm that automatically controls the release of bullets, including one or more sensors that provide real-time sensor data of the view in front of the firearm, a computer that identities legitimate targets in the real-time sensor data, without user intervention, a trigger sensor that determines directly or indirectly if the trigger is engaged, wherein as long as the trigger is engaged, the firearm is configured to continuously acquire real-time sensor data, identify legitimate targets and automatically release bullets when the firearm is directed toward the identified targets.

In an example, the firearm includes a firearm sight and an inertial measurement unit (IMU) mounted on the firearm sight. The IMU configured to determine an azimuth jitter and an elevation jitter corresponding to a movement of the firearm, compute an average response of the azimuth jitter and an average response of the elevation jitter, and generate an output signal to compensate for the movement of the firearm based on the average response of the azimuth jitter and the average response of the elevation jitter. The firearm further includes a firing actuation unit communicatively coupled to the IMU to delay a fire command based on the output signal.

In an example, the firearm includes a firearm sight and an inertial measurement unit (IMU) mounted on the firearm sight. The IMU configured to determine an azimuth jitter and an elevation jitter corresponding to a movement of the firearm, compute an average response of the azimuth jitter and an average response of the elevation jitter, and generate an output signal to compensate for the movement of the firearm based on the average response of the azimuth jitter and the average response of the elevation jitter. The firearm further includes a firing actuation unit communicatively coupled to the IMU to delay a fire command based on the output signal.