The present disclosure provides systems and techniques for determining whether a user is holding a gun. The gun may include a sensor, such as a laser proximity sensor, a capacitive proximity sensor, a load cell, an accelerometer, or a biometric sensor, and the gun may determine whether a user is holding the gun based on an output generated by the sensor. A processor housed in the gun may identify activation of a proximity sensor, determine that a user is holding the gun based on the activation of the proximity sensor, and perform an action in response to determining that the user is holding the gun. The action performed by the processor may include performing a boot procedure, performing a health check procedure, visually indicating state information about the gun, audibly indicating state information about the gun, or tactilely indicating state information about the gun.

Devices for securing and retaining firearms that include either a lockable firearm cabinet or a firearm securement system. The cabinet includes a receptacle; a locking device and locking mechanism; a spring for biasing the locking mechanism in the locked position; and a bar for overriding the locking mechanism. The securement system includes a wall mounted plate for securing a firearm thereto; a release mechanism that allows the firearm to be removed and electronics for wirelessly communicating with a computer and the firearm to provide information regarding removal of the firearm or firearm cartridge from the wall mounted plate.

The invention describes a system for or recording the usage of a firearm and helping a user during usage of the firearm using multiple sensors to gather various information. The system includes a plurality of sensors to record various usage and status data of the firearm. The system further includes a communication module communicatively coupled to the sensors. The communication module is further connected to a processor. The system further includes a memory, a clock chip and an information disseminating device that includes a communication port. The plurality of sensors are configured to gather various information about a firearm device that may be a pistol, a revolver, a gun, etc. after being attached to the firearm device. In addition to the operational information, some of the sensors out of the plurality of sensors may gather information about surrounding environment of the firearm like lighting conditions, wind flow etc. to help a user of the firearm device to use it efficiently.

A system that creates an environment (e.g., ecosystem) for using, transmitting, and storing data from a CEW and other equipment. The information from a CEW includes a log maintained by the CEW. The log may include information related to the operation, maintenance, software, and deployment units used by the CEW. The information may be used alone or in combination with other information received and stored by an evidence management system for managing inventory, generating use-of-force reports, incident reports, and/or providing information related to equipment, such as a CEW, to the supplier of the equipment. Sources of information provided to an evidence management system includes equipment suppliers, CEWs, other cooperating equipment, records management systems of an agency, a dispatch system of an agency, and third parties. A CEW or other equipment may also receive information for storing in the log.

A method authenticates a user before the user can remove or attach a component to a firearm. When the user is authenticated, the user can remove or attach a component to the firearm. The firearm prevents the removal or attachment of the component when the user is not authenticated.

In accordance with disclosed embodiments, there are provided systems, methods, and apparatuses for implementing video shooting guns and personal safety management applications. An exemplary personal safety device may include, for example, a processor and a memory to execute instructions; a rechargeable battery to electrically power the personal safety device; a front facing video camera to capture video data of a scene anterior to a front face of the personal safety device; a rear facing video camera to capture video data of a scene posterior to a rear of the personal safety device; an audio capture device to capture audio data from an environment within which the personal safety device is to operate; a trigger to initiate recording of the front facing video camera, the rear facing video camera, and the audio capture device when triggered by an operator of the personal safety device; and a transceiver to transmit the recorded video data from the front and rear cameras and the captured audio data to a remote location over a network. According to another embodiment, a holster operates in conjunction with a body camera to activate audio and video capture and streaming upon removal of a firearm from the holster. Other related embodiments are disclosed.

A firearm safety lock that includes a rotatable locking member for being moved into a lock position against a trigger guard of the firearm responsive to movement of the firearm into a holster to prevent removal of the firearm from the holster when in the lock position. An electronic circuit is mounted on the holster and operable to cause the locking rotor to move from the lock position into an unlock position responsive to movement of a coded key paired with a code programmed in the electronic circuit into a predetermined proximity to the electronic circuit.

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.

An Internet of Things (IoT) Automated Intelligence Module (AIM) (or sensor module) is mounted on a firearm to gather weapons intelligence data (including video/audio data) when a critical event, such as the firearm un-holstering, and/or discharge, as well as emergency situation, is (are) detected. The IoT sensor module is capable of immediate detection of un-holstering of the firearm, firearm discharge(s), the number of the discharges, as well as 3-D positioning of the firearm at the time of discharge, and notification alerts to designated recipients (i.e., computer aided dispatch, commanders, supervisors, superintendents, etc.) of the firearm status change or critical events in the field. The captured video/audio and the weapon's intelligence data are transmitted to end-users' application desktops, mobile devices, and/or web-based interfaces to provide the designated recipients with situational awareness of personnel in the field and crucial information that can be used for post crime scene analysis.

A monitoring apparatus and system for recording, differentiating, and reporting the discharge of firearms. The monitoring apparatus can be mounted to a firearm and may be automatically activated when the firearm is drawn from a holster thus enabling the monitoring apparatus to record information such as sound, video, location, time, and the like. The apparatus may use this information to differentiate between shots fired by the firearm and shots fired by other firearms. The device may report this distinction to a remote computer configured to receive updates from the weapon mounted apparatus in real time. The remote computer may display the information on a user interface such as a map display, and/or distribute the information according to rules defining how the information should be processed.