A firearm safety system and method is disclosed. The firearm safety system includes motion and location sensors in a device that is attached to a firearm. When the motion sensor detects movement, it causes the location sensor to send a notification to the owner of the firearm on a mobile device or another computing platform. The owner interacts with an application receiving the notification to take steps to prevent the misuse of the firearm.

A firearm-safety-sensing camera-light-laser system apparatus and method, providing a camera that is automatically activated upon the release of the firearm's safety control, and providing a light and a laser pointer, each of which can be automatically activated upon the release of the safety, ensuring that the camera will record events in the firearm's line of fire, starting with the anticipation of discharge of the weapon, associated with release of the safety, and optionally to log and notify an appropriate authority of the release of the safety.

A firearm safety system and method is described herein. The system may include a tracking system, a smart firearm and/or a smart magazine, and a smart tracking unit. The tracking system is in communication with satellites that monitor specific locations, a smart firearm and a portable electronic device. The tracking system includes an internal geographical database of specific monitored locations. The smart firearm includes a microprocessor and a receiver. The motor operates in response to a signal received, which may indicate that the firearm is approaching a no gun safety zone, whereby the signal causes the microprocessor to operate the automatic safety lock to prevent the apparatus from operating. The receiver monitors signals and receives location data from the satellites. The method of operating a smart firearm includes receiving a signal at the at least one receiver and responding to the signal by locking the automatic safety lock.

Systems and methods are provided for firearm monitoring, including a server device running application software that receives signals from firearms regarding usage thereof and a controller running application software configured to communicate with a connected device via a communication interface, detect a jamming signal that inhibits communication with the connected device, stop, in response to detecting the jamming signal, communication with the connected device, and harvest, in response to detecting the jamming signal, power from the jamming signal via a wireless-energy harvesting mechanism having a receiving antenna configured to receive the jamming signal, a rectifier configured to convert the received signal to direct current, and a DC-DC converter configured to alter voltage of the direct current to a desired voltage.

A device and system for firearm tracking capable of tracking firearm location and status while limiting un-authorized use of a firearm. The device featuring a housing that is compatible with a firearm magazine-well wherein once secured to a firearm the device may not be disassociated therefrom rendering the firearm non-functional.

A weapon management system includes a management device, interface units, software downloaded into the interface units, a power network, and a communication network. The power network provides electrical power to the management device and the interface units. The communication network connects the management device to the interface units for transferring electrical signals and data between the components. The interface units and the software downloaded into the interface units are highly reconfigurable, allowing for simple, easy, and fast configurability and expandability for evolving weapon systems. Further, the weapon management system has the capability to add interface units to an existing architecture for expanding and evolving weapon systems.

Systems and methods are provided for firearm event monitoring, including an inertial measurement unit and a hall-effect sensor mounted on a firearm, a server device running application software that receives signals from the inertial measurement unit and the hall-effect sensor, and a machine learning module configured to create and run identification algorithms, using data derived from the received signals from the inertial measurement unit and the hall-effect sensor indicative of a discharge event type, wherein the discharge event type is one of an ammunition discharge event, a misfire discharge event or a dry-fire discharge event.

Firearms being used by non-authorized individuals have been the cause of the death of many innocent people. Guns and rifles are relatively easy to obtain illegally though black markets or by stealing from relatives and acquaintances of registered firearm owners and there is no adequate methods of restricting their operation after they are not controlled by the owner. The current disclosure describes an apparatus and system for remotely monitoring the location, movement and operational status of a firearm and report the status to the firearm owner. Alternatively, the system will track the firearms location and status and report to a central authority when the firearm is fired. This method of operation can be used to notify a central authority to provide backup for an officer under fire. Shots fired and shots heard are detected using acoustic time of flight and sound signature analysis. The detection apparatus being contained within the firearm. In addition, the system uses multiple communication channels to connect with the central authority or firearm owner, including cellular, Wi-Fi, Bluetooth, Lora wan. These communication channels may send firearm discharge information through the cellular or land line 911 system

The present device is an electronically controlled safety system for use in firearms comprising a shape memory actuator configured to connect a mechanical locking interface to a trigger mechanism interface comprising a point of connection to a firearm's trigger mechanism. This shape memory actuator can be controlled by use of an authentication system comprising an RFID module and a control module. The user of the firearm can provide authorization to place the firearm in the armed position by placing an RFID tag having a certain activation code near the RFID module, which can then activate the shape memory actuator through the control module. When the mechanical locking interface is connected to the trigger mechanism interface a firearm's trigger mechanism is locked in place and the firearm is in a safe position and when it is not connected to the trigger mechanism it is in an armed position.

A firearm includes a firearm identification tag carried in a space between lugs of an accessory mounting rail. A firearm accessory mounting rail assembly includes a firearm identification tag carried in a recoil groove of a Picatinny rail, and including a housing having geometry complementary to a lug of the Picatinny rail, and a transmitter carried in the housing. A firearm identification tag for a firearm accessory mounting rail includes a trapezoidal housing having geometry complementary to Picatinny rail geometry and configured to be press fit between Picatinny lugs, and including sides, a major base, a minor base, and legs between the bases disposed at acute angles to the major base.