An optical positioning aiming system including an optical positioning subsystem (subsystem). The subsystem is configured to determine relative positions of a weapon and a head mounted display. The subsystem includes a processing unit, infrared (IR) emitters mounted to a weapon, IR emitters mounted to the head mounted display, IR cameras mounted to the weapon, and IR cameras mounted to the head mounted display. The IR cameras mounted to the weapon are configured to determine a relative position of the IR emitters mounted on the head mounted display and to communicate the relative position of the IR emitters mounted on the head mounted display to the processing unit. The IR cameras mounted to the head mounted display are configured to determine a relative position of the IR emitters mounted to the weapon and communicate the relative position of the IR emitters mounted to the weapon to the processing unit.

An optical positioning aiming system including an optical positioning subsystem (subsystem). The subsystem is configured to determine relative positions of a weapon and a head mounted display. The subsystem includes a processing unit, infrared (IR) emitters mounted to a weapon, IR emitters mounted to the head mounted display, IR cameras mounted to the weapon, and IR cameras mounted to the head mounted display. The IR cameras mounted to the weapon are configured to determine a relative position of the IR emitters mounted on the head mounted display and to communicate the relative position of the IR emitters mounted on the head mounted display to the processing unit. The IR cameras mounted to the head mounted display are configured to determine a relative position of the IR emitters mounted to the weapon and communicate the relative position of the IR emitters mounted to the weapon to the processing unit.

A weapon is equipped with processing capabilities and can include, inter alia, communication technology, geographic positioning systems, a camera, memory and the ability to enable or disable the weapon remotely. Through the application of various protocols (e.g., access, monitor, control, programming), a weapon can be designated for one or more authorized users, and will not operate when not being used by an authorized user. Other implementations include smart ammunition that can also be programmed for a specific user, or more preferably for a specific weapon, such that the weapon and/or the ammunition would not work without the other, and only by the registered authorized user of the same.

The various embodiments herein provide a fire restraining device for selective target shooting in a weapon with a safety lock comprises an infrared sensor, a central computing unit, and a rack and pinion or a shot pin module. The infrared sensor detects a temperature of a target in front of a nozzle of the weapon. The infrared sensor is connected to the central computing unit. The infrared sensor sends the temperature data of the target to the central computing unit. The rack and pinion module or the shot pin module is connected with the central computing unit at one side and the safety lock on another end. The present fire restraining device allows a gunner to control the firing shots over a human or unwanted targets which reduces false fatalities in close combats.

The various embodiments herein provide a fire restraining device for selective target shooting in a weapon with a safety lock comprises an infrared sensor, a central computing unit, and a rack and pinion or a shot pin module. The infrared sensor detects a temperature of a target in front of a nozzle of the weapon. The infrared sensor is connected to the central computing unit. The infrared sensor sends the temperature data of the target to the central computing unit. The rack and pinion module or the shot pin module is connected with the central computing unit at one side and the safety lock on another end. The present fire restraining device allows a gunner to control the firing shots over a human or unwanted targets which reduces false fatalities in close combats.

An automated human transported weapon system is comprised of a computing subsystem, a barrel to fire munitions through to propel the munitions towards a selected target in an area of sighting of the weapon system at a firing time. The computing subsystem provides means for identifying available targets in the area of sighting, means for determining the selected target from the available targets in the area of sighting, responsive to the computing subsystem, means for determining the selected target's position at said firing time, means for positioning aim of weapon, responsive to the computing subsystem, so that the munitions when fired at the firing time will strike the selected target, and, means for activating a trigger signal for firing the munitions at the firing time, responsive to the computing subsystem. The munitions is fired towards the selected target at the firing time. The trigger signal is responsive to a user input. In one embodiment, there are a plurality of types of targets from which to select the selected target. One of the types of targets is identified as a selected type; and, one said target of the selected type is selected to be the selected target.

Systems, devices, and methods, wherein a device is attachable to a firearm and includes a pressure sensor configured to sense pressure generated from the firearm and provide a corresponding signal, a weapon movement sensor configured to sense at least one movement of the firearm and provide a corresponding signal, at least one processor; and memory including computer instructions, the computer instructions configured to, when executed by the at least one processor, cause the at least one processor to determine an event of the firearm based on the corresponding signal provided by the pressure sensor and the corresponding signal provided by the weapon movement sensor. Systems that include the device may record event data and transmit the event data to various user systems for situational awareness, record keeping, training, and other organizational or legal-process purposes.

Systems, devices, and methods, wherein a device is attachable to a firearm and includes a pressure sensor configured to sense pressure generated from the firearm and provide a corresponding signal, a weapon movement sensor configured to sense at least one movement of the firearm and provide a corresponding signal, at least one processor; and memory including computer instructions, the computer instructions configured to, when executed by the at least one processor, cause the at least one processor to determine an event of the firearm based on the corresponding signal provided by the pressure sensor and the corresponding signal provided by the weapon movement sensor. Systems that include the device may record event data and transmit the event data to various user systems for situational awareness, record keeping, training, and other organizational or legal-process purposes.

A friendly fire avoidance system the system that is implemented in any arena involving weaponry and people, such as hunting, policing, military, emergency services, the system using a plurality of specialized navigation and communication devices ‘NCD’, that are wirelessly associated with one another and in communication with one another forming a MESH network, each NCD utilized in the system is associated with a friendly asset.

A friendly fire avoidance system the system that is implemented in any arena involving weaponry and people, such as hunting, policing, military, emergency services, the system using a plurality of specialized navigation and communication devices ‘NCD’, that are wirelessly associated with one another and in communication with one another forming a MESH network, each NCD utilized in the system is associated with a friendly asset.