A firearm, the firearm comprising: a grip; a transparent window located on the rear of the grip; at least one electromagnetic sensor located within the grip, and configured to receive electromagnetic radiation from outside of the grip through the transparent window; a computing device located in the grip and in communication with the LED and the electromagnetic sensor; where the electromagnetic sensor is configured to detect incoming electromagnetic radiation traveling through the transparent window from outside of the grip; and the computing device is configured to allow the firearm to fire if the computing device determines that the incoming electromagnetic radiation corresponds to an authorized user for the firearm. A firearm system, the firearm comprising: an external charging circuit, the external charging circuit comprising: a resonant inductive coil; a power supply in operable communication with the coil; a rechargeable power storage device in operable communication with the coil; a firearm configured to removably connect to the external charging circuit, the firearm comprising: a resonant inductive coil; a power supply in operable communication with the coil; a rechargeable storage device in operable communication with the coil; firearm electronics in operable communication with the power supply; mechanical controls in operable communication with the power supply; a mechanical squeeze generator in operable communication with the power supply.

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 comprised of 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 an 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 the mechanical locking interface is not connected to the trigger mechanism is in an armed position.

A lockable gun mount features a stock receiver, a trigger block, and a barrel lock. The stock receiver includes a base, sidewalls, a receiving aperture, and one or more fasteners. The trigger block includes a trigger rod and a wall member. The barrel lock includes a wall member, a hinged door coupled to the wall member, and a locking mechanism configured to secure the hinged door to the wall member. In some examples, the barrel lock further includes a biometric sensor. A cumulative force between the stock receiver, the trigger receiver, and the barrel lock prevents the gun from being removed from the lockable gun mount when secured to a wall or flat surface.

The present disclosure provides systems and techniques for authenticating biometric data while protecting user privacy. Aspects of the present disclosure include collecting biometric query data at a biometric sensor of the gun, generating a set of query features from the biometric query data, each query feature of the set of query features including a first number of dimensions, generating a projection matrix, each element of the projection matrix being drawn independently from an identical distribution having zero mean and unit variance, transforming the set of query features into a transformed set of query features according to the projection matrix, retrieving a transformed set of enrollment features from memory of the gun, identifying a data match based on the transformed set of query features and the transformed set of enrollment features satisfying a similarity threshold, and unlocking the gun in response to the identifying the data match.

Systems and methods are provided for the making safe of a handgun. A safety system includes a lock mechanism coupled to an engagement member and a user interface. The engagement member is movably coupled to the handgun and includes a contact face that is in contact with the slide of the handgun. The engagement member transfers a portion of a force to the slide and moves between a lock position and an unlock position. The lock position corresponds to a separation distance between a distal end of a primer actuator of the handgun and a primer activation plane. The engagement member is configured to transition between the lock position and the unlock position while remaining movably coupled to the handgun. Movement of the engagement member from the lock position is restricted by the lock mechanism until disengaged via the user interface.

Provided is a method that includes determining a device geolocation based on a satellite signal received by a weapon-tracking device and receiving a sensor reading using a sensor attached to the weapon-tracking device, wherein the sensor is sensitive to a use of the weapon. The instructions include determining that a change in the sensor reading satisfies a change threshold and, in response to a determination that the change threshold is satisfied, transmitting device state data to a wireless signal receiver via a wireless signal, wherein the device state data comprises a device identifier and the device geolocation. The instructions further include storing the device identifier and the device geolocation in a data server in communication with the wireless signal receiver and transmitting a message based on the device identifier and device geolocation to a client from the data server.

A system of weapon oversight and control is revealed. One or more Authorized Weapon Operators are authenticated, and the weapons are authorized for use by a Remote Authority who is updated in real time by 360 by 360 video and sound as to who is wielding the weapon, the location of the weapon, and the current use of the weapon. The weapon is authorized and deauthorized to fire or not fire by the Remote Authority, giving oversite and operability of the weapon to the Remote Authority.

Systems for universally locking a trigger of a firearm are provided that require authentication to transition the firearm to an unlocked state. In general, examples of the systems for universally locking a trigger of a firearm described herein are located in an interchangeable grip portion of the firearm or mounted to an accessory rail of the firearm. Embodiments of the system generally include trigger interference or blocking members to prevent actuation of the trigger until the authentication system has authorized the user to fire the firearm. Once the system is authenticated, embodiments of the system remain in an unlocked state while the user is grasping the firearm. When the user removes their hand from the firearm, embodiments of the trigger locking system automatically returns to a locked state, reducing or eliminating unauthorized use of the firearm.

A portable camera may be activated in response to the activity of a firearm. Furthermore, an individual who discharged a firearm may be identified. Furthermore, information related to the firing of a firearm may be recorded, assessed, identified and transmitted. Furthermore, the status of an implement at a mount may be monitored. Furthermore, a charging device for delivering electrical power to components of a firearm may be used. A communications channel may be established between a firearm telematics sensor and a video camera, optionally by means of intermediary devices. A communications channel may be established between a mount (e.g., holster) telematics device and local and/or remote monitoring service components, optionally by means of intermediary devices. When the telematics sensor detects that its associated firearm has been removed from a holster, is in motion, or is being discharged, the telematics sensor may signal the video camera to initiate recording.

A method of confirming the identity of a person who issued a token to signify eligibility for a privilege. Possession token is confirmed to be by the same person by using sensors in the token which track the movements of the person. A machine learning system is trained to evaluate the sensor data detecting transfer of possession of the token. The state of continuous possession since the token was issued or set to an enabled state is confirmed and the privilege is granted. The method of identity confirmation is used in various contexts such as for to control entry to a location, use of a facility or service. It is also useful to determine continuous possession of a weapon to prevent misuse after the weapon is stolen, dropped or lost. Servers, beacons and outside sources of data or inputs to be measured by the sensor can also be used.