Firearm positioning management system

By using electronic tags and locator systems to monitor the location of firearms in real time, the problem of untimely updates to firearm location information in existing technologies has been solved, realizing intelligent and automated firearm management and improving the safety and efficiency of management.

CN122155132APending Publication Date: 2026-06-05BEIJING BAXIN TECHNOLOGY SERVICE CO LTD +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Applications(China)
Current Assignee / Owner
BEIJING BAXIN TECHNOLOGY SERVICE CO LTD
Filing Date
2024-12-03
Publication Date
2026-06-05

AI Technical Summary

Technical Problem

The existing gun management system is unable to update and uniformly monitor the location information of guns in a timely manner, resulting in fragmented management and a lack of effective automatic control.

Method used

The system employs electronic tags and locators, including a reader module, a satellite positioning module, a motion detection module, an alarm module, and a communication module. These modules monitor the location and status of the firearm in real time, promptly issue alarm control commands, and transmit information to the back-end data management platform.

Benefits of technology

It enables real-time monitoring and positioning of firearms, preventing illegal carrying and use, improving the safety and efficiency of management, realizing the intelligence and automation of firearm management, and enhancing the accuracy and response speed of management.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a gun positioning management system, comprising: an electronic tag; a locator and a background data management platform, the locator comprising a reader module, a satellite positioning module, a motion state detection module, an alarm module, a control module and a communication module; the control module determines whether to send an alarm control instruction according to information detected by the reader module and / or the satellite positioning module and / or the motion state detection module; and / or, in the case that the control module determines to send the alarm control instruction, the control module controls the alarm module to send an alarm signal; and / or, in the case that the control module determines to send the alarm control instruction, the control module transmits the alarm control instruction to the background data management platform through the communication module, and sends an alarm instruction through the background data management platform. Through the technical scheme provided by the application, the technical problem that the position information of a gun cannot be monitored in time in the prior art can be solved.
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Description

Technical Field

[0001] This invention relates to the field of gun location management technology, and more specifically, to a gun location management system. Background Technology

[0002] Currently, gun control provides a foundation for ensuring public safety, preventing violent crime, and maintaining social stability. However, the management is complex due to the different scenarios, uses, and nature of gun use. Existing gun control technologies mainly focus on registration, licensing, review, use, retrieval, return to storage, and destruction, always revolving around the management of gun users, user units, and the guns themselves.

[0003] However, existing gun management platforms have the following problems: information management of gun users, user units, and guns themselves is scattered, lacking unified automatic monitoring, management, and control, and unable to update and manage gun location information in a timely manner. Summary of the Invention

[0004] The main objective of this invention is to provide a gun location management system to solve the technical problem that existing technologies cannot monitor the location information of guns in a timely manner.

[0005] To achieve the above objectives, the present invention provides a gun positioning and management system, comprising:

[0006] An electronic tag, used to be installed on a firearm, contains electronic firearm registration information;

[0007] The locator and backend data management platform include a reader module, a satellite positioning module, a motion state detection module, an alarm module, a control module, and a communication module. The reader module, the satellite positioning module, the motion state detection module, and the alarm module are all signal-connected to the control module, and the control module is signal-connected to the communication module. The reader module is used to identify the electronic gun certificate information, the satellite positioning module is used to obtain the location information of the locator, and the motion state detection module is used to detect the motion state of the locator.

[0008] The control module determines whether to issue an alarm control command based on the information detected by the reader module and / or the satellite positioning module and / or the motion state detection module.

[0009] When the control module determines to issue an alarm control command, the control module controls the alarm module to issue an alarm signal; and / or,

[0010] When the control module determines to issue an alarm control command, the control module transmits the alarm control command to the background data management platform through the communication module, and issues the alarm command through the background data management platform.

[0011] Furthermore, the reader module is used to identify the electronic gun certificate information within a preset distance range;

[0012] When the reader module identifies the electronic gun certificate information within the preset distance range, the control module determines that the firearm is within a controllable range;

[0013] When the reader module fails to identify the electronic gun certificate information within the preset distance range, the control module controls the alarm module to issue a first alarm signal; and / or, the background data management platform issues a first alarm command.

[0014] Furthermore, when the satellite positioning module detects that the locator is within a preset activity range, and the motion state detection module detects that the locator's position has not changed within a predetermined time period, the control module controls the alarm module to issue a second alarm signal; and / or, the background data management platform issues a second alarm command.

[0015] Furthermore, when the satellite positioning module detects that the locator has exceeded a preset activity range, the control module controls the alarm module to issue a third alarm signal; and / or,

[0016] When the satellite positioning module detects that the locator has exceeded the preset activity range, the background data management platform issues a third alarm command and adjusts the preset activity range through the background data management platform.

[0017] Furthermore, the gun positioning management system also includes:

[0018] The trajectory mapping module is connected to the background data management platform and is used to determine the motion trajectory of the locator based on the position information of the satellite positioning module.

[0019] The map data storage module is connected to the background data management platform by a signal. The map data storage module is used to obtain the corresponding path planning information based on the location information of the satellite positioning module.

[0020] The trajectory prediction module is connected to both the trajectory mapping module and the map data storage module. The trajectory prediction module compares the movement trajectory of the locator determined by the trajectory mapping module with the path planning information obtained by the map data storage module to plan the optimal path.

[0021] Furthermore, the gun positioning management system also includes an information acquisition module, which is used to acquire the communication contact information of the communication device of the staff member bound to the locator. The information acquisition module is signal-connected to the trajectory prediction module. The communication module is signal-connected to the information acquisition module and is used to transmit alarm control commands and / or the optimal path issued by the control module to the staff member's communication device; and / or...

[0022] The communication module is a 4G private network module.

[0023] Furthermore, when the motion state detection module detects that the locator is stationary for a first preset time period, the control module controls the satellite positioning module to be in a silent state; when the motion state detection module detects that the locator is in motion or that the locator is not stationary for the first preset time period, the control module controls the satellite positioning module to be in an active state; and / or,

[0024] When the reader module recognizes the electronic gun certificate information within a preset working frequency, the control module controls the reader module to reduce the working frequency; when the reader module does not recognize the electronic gun certificate information within the preset working frequency, the control module controls the reader module to maintain the current working frequency or increase the working frequency; and / or,

[0025] When the motion state detection module detects that the locator is stationary within a second preset time period, the control module controls the communication module to reduce its operating frequency; when the motion state detection module detects that the locator is not stationary within the second preset time period, the control module controls the communication module to maintain the current operating frequency or increase its operating frequency.

[0026] Furthermore, the locator is linked to the electronic tag via radio frequency communication; and / or,

[0027] The electronic tag contains projectile count information. The reader module is used to acquire the projectile count information. The communication module transmits the projectile count information and the corresponding locator location information to the background data management platform. The background data management platform then sends the projectile count information and the corresponding locator location information to the communication module of the locator that is active within a preset activity range.

[0028] Furthermore, the locator also includes:

[0029] An information storage module, which is signal-connected to the reader module, the alarm module, the control module, and the satellite positioning module, is used to store information from the reader module, the alarm module, and the satellite positioning module; and / or,

[0030] The alarm module includes at least one of an alarm light, a sounder, and an alarm information sending unit.

[0031] Furthermore, the locator also includes:

[0032] A communication interface is provided for communication with the gun cabinet management platform; when the communication interface is connected to the gun cabinet management platform, the control module controls both the reader module and the alarm module to be powered off; and / or,

[0033] The device includes a charging interface, a power detection module, and a battery module. The charging interface is used for electrical connection with a charger. The power detection module is connected to the battery module and is used to detect the charging level of the battery module. When the power detection module detects that the battery module is fully charged, it controls the charging interface to disconnect from the charger. When the power detection module detects that the charging level of the battery module is lower than a preset power value, it controls the charging interface to connect to the charger.

[0034] By applying the technical solution of this invention, real-time monitoring and positioning of firearms are achieved, effectively preventing the illegal possession and use of firearms and improving the safety and efficiency of firearm management. The system's functional modules, including radio frequency communication, satellite positioning, motion detection, and information storage, not only monitor the location of firearms in real time but also record their usage, providing comprehensive data support for firearm management. Furthermore, through linkage with the gun cabinet management platform and staff communication equipment, intelligent and automated firearm management is achieved, further improving management accuracy and response speed. The system design fully considers the needs of practical applications, such as power management and operating frequency adjustment, ensuring stable operation and long-term monitoring capabilities, providing strong technical support for firearm safety management. Attached Figure Description

[0035] The accompanying drawings, which form part of this application, are used to provide a further understanding of the invention. The illustrative embodiments of the invention and their descriptions are used to explain the invention and do not constitute an undue limitation of the invention. In the drawings:

[0036] Figure 1 A schematic diagram illustrating the process of a control module issuing alarm control commands according to an embodiment of the present invention is shown.

[0037] Figure 2 A flowchart illustrating the adjustment of the operating state of the satellite positioning module by the control module according to an embodiment of the present invention is shown.

[0038] Figure 3 A flowchart illustrating the adjustment of the operating state of the reader module by the control module according to an embodiment of the present invention is shown.

[0039] Figure 4 A flowchart illustrating how a control module adjusts the operating state of a communication module according to an embodiment of the present invention is shown.

[0040] Figure 5 A schematic diagram of the locator provided according to an embodiment of the present invention is shown.

[0041] The above figures include the following reference numerals:

[0042] 100. Reader module;

[0043] 200. Alarm module;

[0044] 300. Control module;

[0045] 400. Satellite positioning module;

[0046] 500. Motion state detection module;

[0047] 600. Communication module. Detailed Implementation

[0048] It should be noted that, unless otherwise specified, the embodiments and features described in this application can be combined with each other. The present invention will now be described in detail with reference to the accompanying drawings and embodiments.

[0049] like Figure 5 As shown, an embodiment of the present invention provides a firearm positioning and management system. This system includes an electronic tag, a locator, and a backend data management platform. The electronic tag is installed on the firearm and contains electronic firearm license information. The locator includes a reader module 100, a satellite positioning module 400, a motion detection module 500, an alarm module 200, a control module 300, and a communication module 600. The reader module 100, satellite positioning module 400, motion detection module 500, and alarm module 200 are all signal-connected to the control module 300, which is signal-connected to the communication module 600. The reader module 100 is used to identify the electronic firearm license information, the satellite positioning module 400 is used to acquire the locator's location information, and the motion detection module 500 is used to detect the locator's motion state. Wherein, as... Figure 1As shown, the control module 300 determines whether to issue an alarm control command based on the information detected by the reader module 100 and / or the satellite positioning module 400 and / or the motion state detection module 500. If the control module 300 determines to issue an alarm control command, it controls the alarm module 200 to issue an alarm signal; and / or, if the control module 300 determines to issue an alarm control command, it transmits the alarm control command to the background data management platform via the communication module 600, and issues the alarm command through the background data management platform.

[0050] The firearms location management system provided in this embodiment can not only verify the electronic firearms certificate information through the reader module 100 of the locator, but also monitor the location information and status of personnel carrying the locator through the satellite positioning module 400 and motion detection module 500 of the locator. Furthermore, the locator's control module 300 can determine whether to issue an alarm control command, and the alarm module 200 of the locator can issue an alarm signal. Alternatively, the alarm control command can be transmitted to the back-end data management platform through the communication module 600, after which the back-end data management platform issues an alarm command. In this way, the locator can achieve a multi-functional integration and communicate with the back-end management system, facilitating information integration by the back-end management system for better firearms management, further improving management accuracy and response speed. Therefore, the firearms location management system provided in this embodiment can solve the technical problem of the inability to monitor the location information of firearms in a timely manner in the prior art.

[0051] Furthermore, the firearms location management system provided in this embodiment allows the locator and the firearm to be separate modules, eliminating the need to install the locator directly on the firearm. Instead, the locator is simply bound to the electronic firearm registration information of the corresponding firearm requiring monitoring, without requiring any modifications to the firearm. During use, personnel only need to carry the locator to monitor and manage the firearms.

[0052] Specifically, by incorporating a communication module 600, the location, movement status, and alarm information of firearms can be transmitted in real time to the backend data management platform. This facilitates remote monitoring and management by administrators, making it suitable for large firearms management organizations such as police stations and the military, enabling centralized management and dispatch of firearms. In terms of implementation effectiveness, the addition of the backend data management platform allows administrators to remotely monitor the use and location of firearms, improving management flexibility and efficiency. In application scenarios, such as large firearms management organizations like police stations and the military, it enables centralized management and dispatch of firearms, improving the efficiency of firearms utilization.

[0053] The addition of the satellite positioning module 400 enables the system to locate firearms globally. This is a highly practical function for police or military personnel conducting transnational operations, allowing them to monitor the real-time location of firearms and prevent loss or theft during missions. In terms of implementation, the satellite positioning module 400 provides the system with global positioning capabilities. Regardless of the firearm's location, the system can obtain its location information in real time. This provides real-time location information for police or military personnel conducting transnational operations, preventing the loss or theft of firearms. In application scenarios, global positioning and real-time monitoring of firearms can be achieved in areas such as international peacekeeping missions and transnational anti-drug operations.

[0054] Specifically, the satellite positioning module 400 can be a BeiDou satellite navigation and positioning unit. When the BeiDou satellite navigation and positioning unit of the locator is operational, it utilizes the sub-meter level high-precision positioning advantage of BeiDou to enable civil servants carrying locators and firearms to move within a controllable range or area. The relevant activity trajectories can be displayed in real-time on a map in the background. Simultaneously, based on the requirements of the mission, the movement range of the locator and firearms can be set in the background. This is manifested by setting the latitude and longitude range of the locator on the map. If within a controllable area, the locator operates normally. If abnormal situations occur, such as exceeding boundaries or prolonged inactivity, various warning messages are issued in conjunction with vibration sensing, RFID reading, and other information, such as flashing lights, buzzer sounds, and information notifications.

[0055] In this embodiment, the motion state detection module 500 can be a vibration sensor.

[0056] In this embodiment, the reader module 100 is used to identify electronic gun license information within a preset distance range. When the reader module 100 identifies the electronic gun license information within the preset distance range, the control module 300 determines that the firearm is within a controllable range. When the reader module 100 does not identify the electronic gun license information within the preset distance range, the control module 300 controls the alarm module 200 to issue a first alarm signal; and / or, the background data management platform issues a first alarm command. With this setup, the reader module 100 can effectively monitor the location and status of the firearm. Once the firearm leaves the preset controllable range, the alarm module 200 issues a first alarm signal and / or the background data management platform issues a first alarm command, effectively preventing the theft or illegal use of firearms. This is particularly suitable for institutions such as police and the military that require strict firearm management. In terms of implementation effectiveness, this system can significantly improve the security of firearm management. Once a firearm is illegally carried or used, the system will immediately sound an alarm to prevent possible violent incidents and protect public safety. In terms of application scenarios, such as police stations, military armories, and shooting club training ranges, real-time monitoring and location of firearms can be achieved to prevent firearms from being lost or stolen.

[0057] Specifically, the first alarm signal can be a light, vibration, or sound signal. The first alarm command can be an alarm message directly fed back to the back-end data management platform; or it can be an alarm sound or alarm light emitted by an alarm device connected to the back-end data management platform, so that back-end staff can be informed of the alarm information in a timely manner.

[0058] Specifically, the preset distance range can be within a radius of 3 meters.

[0059] In this embodiment, when the satellite positioning module 400 detects that the locator is within a preset activity range and the motion state detection module 500 detects that the locator's position has not changed within a predetermined time period, the control module 300 controls the alarm module 200 to issue a second alarm signal; and / or, the background data management platform issues a second alarm command. This facilitates timely acquisition of the locator's location information, thereby facilitating real-time acquisition of the location information of the corresponding personnel, and enabling the background data management platform to centrally manage and control the relevant information in a timely manner.

[0060] Specifically, the second alarm signal is different from the first alarm signal. Specifically, when the first alarm signal is a first alert sound, the second alarm signal is a second alert sound; or, the first alarm signal is a light, and the second alarm signal is a sound; as long as the first and second alarm signals can be triggered in different ways, it is acceptable, so that staff can distinguish between the alarm signals in a timely manner.

[0061] Correspondingly, the second alarm command is different from the first alarm command, so that the staff of the back-end management system can quickly distinguish between the different alarm commands.

[0062] Specifically, when the satellite positioning module 400 detects that the locator has exceeded the preset activity range, the control module 300 controls the alarm module 200 to issue a third alarm signal. This allows personnel carrying the locator to promptly know whether their location information is within the set preset activity range, ensuring that their activity range is within acceptable limits.

[0063] Specifically, when the satellite positioning module 400 detects that the locator has exceeded the preset activity range, the background data management platform issues a third alarm command and adjusts the preset activity range accordingly. This allows the background data management platform to promptly obtain the actual location of the staff member carrying the locator and determine whether the preset activity range needs to be adjusted based on the staff member's actual location, work tasks, and work objectives.

[0064] In this embodiment, the gun positioning management system further includes a trajectory mapping module, a map data storage module, and a trajectory prediction module. The trajectory mapping module is signal-connected to the backend data management platform and is used to determine the movement trajectory of the locator based on the location information of the satellite positioning module 400. The map data storage module is also signal-connected to the backend data management platform and is used to obtain corresponding path planning information based on the location information of the satellite positioning module 400. Both the trajectory mapping module and the map data storage module are connected to the trajectory prediction module. The trajectory prediction module compares the movement trajectory of the locator determined by the trajectory mapping module with the path planning information obtained by the map data storage module to plan the optimal path. This facilitates providing optimal paths for personnel carrying locators, enabling them to quickly determine the optimal path based on their work tasks, improving work efficiency and accuracy. It also facilitates the backend management system to comprehensively schedule and manage multiple personnel carrying locators based on work tasks, thereby better optimizing work progress.

[0065] This functionality predicts the trajectory of firearms, providing decision support for firearm deployment and management. For example, during missions, it can predict the possible location of firearms, allowing for timely deployment and support, thus improving mission efficiency and safety. In terms of implementation effectiveness, the addition of the trajectory prediction module allows for the prediction of firearm trajectories, providing decision support for firearm deployment and management, and improving mission efficiency and safety. In application scenarios, it can be used in situations such as police operations, military combat, and shooting training at shooting clubs, all of which enable the prediction of firearm trajectories to provide decision support for firearm deployment and management.

[0066] Specifically, the trajectory mapping module is used to collect the location information detected by the satellite positioning module 400 and transmitted from the communication module 600 to the background data management platform, and to draw the motion trajectory of the locator based on the multiple location information detected by the satellite positioning module 400.

[0067] Specifically, the gun positioning management system also includes an information acquisition module, which acquires the communication contact information of the personnel's communication devices bound to the locator. This information acquisition module is signal-connected to the trajectory prediction module. A communication module 600 is signal-connected to the information acquisition module and transmits alarm control commands and / or optimal paths issued by the control module 300 to the personnel's communication devices. This structural setup allows the optimal path and corresponding alarm control commands to be pushed to the personnel in real time, facilitating their actions based on path planning and improving work efficiency.

[0068] Specifically, the communication module 600 is a 4G private network module. The use of this module ensures the security and stability of information transmission, making it suitable for highly confidential firearms management scenarios, such as special forces and secret police. In terms of implementation effectiveness, real-time optimal path delivery improves staff efficiency, while the 4G private network module guarantees the security and stability of information transmission, preventing information leaks and protecting the safety of firearms and personnel. In application scenarios, real-time path delivery and secure information transmission can be achieved for special forces carrying out covert missions and secret police conducting covert investigations.

[0069] Specifically, the gun positioning management system may also include a display module, which is connected to the communication module 600. The communication module 600 can receive alarm control commands and / or optimal path transmissions from the control module 300 to the staff's communication devices and display the corresponding text information through the display module, so that the staff carrying the locator can know the content of the corresponding alarm control commands and the specific content of the final path in a timely manner, and make it convenient for the staff to confirm their working status.

[0070] Specifically, the locator also includes a power module. The reader module 100, satellite positioning module 400, motion detection module 500, alarm module 200, control module 300, and communication module 600 are all electrically connected to the power module, which provides power to these components. Specifically, the power module can be a battery module.

[0071] like Figure 2 As shown, when the motion detection module 500 detects that the locator is stationary for a first preset time period, the control module 300 controls the satellite positioning module 400 to be in a silent state; when the motion detection module 500 detects that the locator is in motion or that the locator is not stationary for the first preset time period, the control module 300 controls the satellite positioning module 400 to be in an active state. This effectively saves power to the satellite positioning module 400, extending the system's lifespan. It is particularly suitable for long-term firearm monitoring tasks, such as border patrols and field training, reducing power consumption and ensuring long-term stable system operation. In terms of implementation, the addition of the motion detection module 500 allows the system to automatically adjust the working state of the satellite positioning module 400 according to the firearm's movement, saving power and extending the system's lifespan. In application scenarios, such as border patrols and field training, it enables long-term firearm monitoring, reducing power consumption and ensuring long-term stable system operation.

[0072] Specifically, the silent state can be understood as a non-working state, in which no power is consumed.

[0073] like Figure 3 As shown, when the reader module 100 identifies the electronic gun certificate information within a preset operating frequency, the control module 300 controls the reader module 100 to reduce its operating frequency; when the reader module 100 does not identify the electronic gun certificate information within the preset operating frequency, the control module 300 controls the reader module 100 to maintain the current operating frequency or increase its operating frequency. This dynamic adjustment of operating frequency design can further save power, extend the system's service life, and ensure the system's monitoring efficiency. It is suitable for scenarios requiring long-term monitoring, such as border patrols and field training, reducing power consumption and ensuring the long-term stable operation of the system. In terms of implementation effect, this design can achieve dynamic adjustment of the reader module 100's operating frequency, further saving power, extending the system's service life, while ensuring monitoring efficiency and improving the security of gun management. In terms of application scenarios, such as border patrols and field training, it can achieve long-term monitoring of guns, reduce power consumption, and ensure the long-term stable operation of the system.

[0074] like Figure 4 As shown, when the motion detection module 500 detects that the locator is stationary within a second preset time period, the control module 300 controls the communication module 600 to reduce its operating frequency; when the motion detection module 500 detects that the locator is not stationary within the second preset time period, the control module 300 controls the communication module 600 to maintain the current operating frequency or increase its operating frequency. This design of dynamically adjusting the operating frequency of the communication module 600 can further save power, extend the service life of the system, and ensure the normal communication of the locator.

[0075] Specifically, during task execution, the locator is in working condition. Based on information such as whether the RFID reader can read the firearm's license information, the frequency information of Beidou positioning, the motion and stillness information sensed by the vibration sensor, and the frequency of information transmission through the 4G private network, various information fusion decision-making mechanisms are formed. For example, the working frequency of the RFID reader is reduced or stopped, the Beidou satellite navigation unit is active / inactive, and the communication frequency of the 4G private network is reduced, so as to achieve low-power operation of the locator and ensure that the locator can work for a longer period of time.

[0076] Specifically, the locator binds information to the electronic tag via radio frequency communication. In practical applications, this radio frequency communication technology enables high-speed and stable information transmission between the electronic tag and the locator, maintaining good communication performance even in complex environments such as metal warehouses and underground parking lots.

[0077] Specifically, the electronic tag contains projectile count information. The reader module 100 acquires this projectile count information, and the communication module 600 transmits the projectile count information and the corresponding locator location information to the backend data management platform. The backend data management platform then sends the projectile count information and the corresponding locator location information to the communication module 600 of the locator operating within a preset activity range. Acquiring the projectile count information effectively provides feedback on the specific usage of the firearm, allowing the backend data management system to promptly understand the specific work status of personnel within the monitored activity range.

[0078] Specifically, when the background data management system combines the received projectile count information with the corresponding location information, if the projectile count within the predetermined area is greater than or equal to a preset value (the preset value can be 1 / 5 of the total number of projectiles from all firearms used to complete the task), the background data management system determines whether dispatch support is needed based on the number of locators within the predetermined area. Specifically, if the number of locators within the predetermined area is greater than or equal to a preset number of locators (the preset number of locators can be 1 / 5 of the total number of locators used to complete the task), the background data management system determines that dispatch support is not needed. If the number of locators within the predetermined area is greater than or equal to a preset number of locators (the preset number of locators can be 1 / 5 of the total number of locators used to complete the task), the background data management system determines that dispatch support is not needed, and selects the locator closest to the predetermined area (the distance to the predetermined area is less than or equal to a preset distance value, specifically 10 meters) based on the location information of each locator outside the predetermined area, and sends the dispatch support information and the location of the predetermined area to the corresponding locator via the communication module 600.

[0079] Specifically, when the projectile count within the designated area is greater than or equal to a preset value (the preset value can be 1 / 5 of the total number of projectiles from all firearms used to complete the task), the background data management system determines whether dispatch support is needed based on the number of locators within the designated area and the remaining number of projectiles. Specifically, the background data management system integrates the projectile information from the locators within the designated area and counts the remaining projectiles. When the remaining number of projectiles from the firearms within the designated area is less than or equal to 1 / 3 of the total number of projectiles from the firearms within the designated area, the background data management system determines that the remaining number of projectiles within the designated area is insufficient. The background data management system will then select the locator closest to the designated area (within a distance range less than or equal to a preset distance value, which can be 10 meters) based on the location information of each locator outside the designated area, and send the dispatch support information and the location of the designated area to the corresponding locator via the communication module 600.

[0080] In this embodiment, the locator also includes an information storage module, which is signal-connected to the reader module 100, alarm module 200, control module 300, and satellite positioning module 400. The information storage module stores information from the reader module 100, alarm module 200, and satellite positioning module 400. Specifically, the alarm module 200 includes at least one of an alarm light, a sounder, and an alarm information transmission unit. The addition of the information storage module enables the system to record the usage and location information of the firearm, providing data support for firearm maintenance and management. The diverse design of the alarm module 200 can meet alarm needs in different scenarios; for example, in a quiet environment, the alarm light can be used for a silent alarm, avoiding unnecessary panic. In terms of implementation effectiveness, the information storage module can record the usage and location information of the firearm, providing data support for firearm maintenance and management. Simultaneously, the diverse design of the alarm module 200 can meet alarm needs in different scenarios, improving alarm efficiency and effectiveness. In application scenarios, such as firearm maintenance, firearm usage records, and firearm location monitoring, information storage and diversified alarm functions can be achieved.

[0081] Specifically, the alarm module 200 can issue alarms such as flashing lights, sounding a buzzer, and sending information notifications.

[0082] Specifically, the locator also includes a communication interface for communicating with the gun cabinet management platform; when the communication interface is connected to the gun cabinet management platform, the control module 300 controls the reader module 100 and the alarm module 200 to be in a powered-off state.

[0083] Specifically, the locator also includes a charging interface, a power detection module, and a battery module. The charging interface is used to electrically connect to the charger; the power detection module is connected to the battery module and is used to detect the charging level of the battery module; when the power detection module detects that the battery module is fully charged, it controls the charging interface to disconnect from the charger; when the power detection module detects that the charging level of the battery module is lower than a preset power value, it controls the charging interface to electrically connect to the charger for charging.

[0084] This design enables seamless integration between the locator and the gun cabinet management platform. When a gun is placed in the cabinet, the locator automatically enters a sleep state to conserve power. Simultaneously, power detection and automatic charging functions ensure long-term stable operation of the locator, making it suitable for various gun management scenarios such as police stations, the military, and shooting clubs. In practical applications, this design allows for seamless integration between the locator and the gun cabinet management platform without manual intervention. The system automatically enters a sleep state to save power, while power detection and automatic charging functions guarantee long-term stable operation of the locator, eliminating concerns about power consumption.

[0085] In this embodiment, the locator was designed to fit the confined space of a handgun. Utilizing IoT technologies such as RFID, BeiDou, 4G / 5G, and sensors, this locator enables precise inventory tracking and accurate control of the firearm's operational status. The locator is integrated with the firearm and gun rack via a charging device and is managed uniformly through a management platform, encompassing the firearm, gun cabinet, and storage room. It provides unified management of personnel tracking, firearm retrieval and return, and firearm usage—meaning 24 / 7, full-time control.

[0086] As can be seen from the above description, the embodiments of the present invention achieve the following technical effects: This firearm positioning management system, through the combination of electronic tags and locators, realizes real-time monitoring and positioning of firearms, effectively preventing the illegal carrying and use of firearms, and improving the security and efficiency of firearm management. The system's radio frequency communication, satellite positioning, motion status detection, and information storage modules not only monitor the location of firearms in real time but also record their usage, providing comprehensive data support for firearm management. Furthermore, through linkage with the gun cabinet management platform and staff communication equipment, intelligent and automated firearm management is achieved, further improving the accuracy and response speed of management. The system design fully considers the needs of practical applications, such as power management and operating frequency adjustment, ensuring stable operation and long-term monitoring capabilities, providing strong technical support for firearm safety management. In practical applications, this system can be widely used in institutions requiring strict firearm management, such as police, military, and shooting clubs. It can not only prevent firearm theft or illegal use but also improve firearm usage efficiency, reduce maintenance costs, and bring revolutionary changes to firearm management. Meanwhile, the system's intelligent design allows managers to remotely monitor the use and location of firearms, improving management flexibility and efficiency and providing technical support for the modernization of firearms management. In terms of implementation effectiveness, this system can improve the security and efficiency of firearms management, preventing theft or illegal use of firearms. Its intelligent design also allows managers to remotely monitor the use and location of firearms, enhancing management flexibility and efficiency. In terms of application scenarios, this system can be widely used in institutions requiring strict firearms management, such as police forces, the military, and shooting clubs, bringing revolutionary changes to firearms management and raising its modernization level.

[0087] It should be noted that the terminology used herein is for the purpose of describing particular embodiments only and is not intended to limit the exemplary embodiments according to this application. As used herein, the singular form is intended to include the plural form as well, unless the context clearly indicates otherwise. Furthermore, it should be understood that when the terms "comprising" and / or "including" are used in this specification, they indicate the presence of features, steps, operations, devices, components, and / or combinations thereof.

[0088] Unless otherwise specifically stated, the relative arrangement, numerical expressions, and values ​​of the components and steps described in these embodiments do not limit the scope of this application. It should also be understood that, for ease of description, the dimensions of the various parts shown in the drawings are not drawn to actual scale. Techniques, methods, and devices known to those skilled in the art may not be discussed in detail, but where appropriate, such techniques, methods, and devices should be considered part of the specification. In all examples shown and discussed herein, any specific values ​​should be interpreted as merely exemplary and not as limitations. Therefore, other examples of exemplary embodiments may have different values. It should be noted that similar reference numerals and letters in the following drawings denote similar items; therefore, once an item is defined in one drawing, it need not be further discussed in subsequent drawings.

[0089] In the description of this application, it should be understood that the orientation or positional relationship indicated by directional terms such as "front, back, up, down, left, right", "horizontal, vertical, horizontal" and "top, bottom" is usually based on the orientation or positional relationship shown in the accompanying drawings, and is only for the convenience of describing this application and simplifying the description. Unless otherwise stated, these directional terms do not indicate or imply that the device or element referred to must have a specific orientation or be constructed and operated in a specific orientation, and therefore should not be construed as a limitation on the scope of protection of this application; the directional terms "inner" and "outer" refer to the inner and outer contours relative to the outline of each component itself.

[0090] For ease of description, spatial relative terms such as "above," "on top of," "on the upper surface of," "above," etc., are used herein to describe the spatial positional relationship of a device or feature as shown in the figures to other devices or features. It should be understood that spatial relative terms are intended to encompass different orientations in use or operation beyond the orientation of the device as described in the figures. For example, if the device in the figures were inverted, a device described as "above" or "on top of" other devices or structures would subsequently be positioned as "below" or "under" other devices or structures. Thus, the exemplary term "above" can include both "above" and "below." The device may also be positioned in other different ways (rotated 90 degrees or in other orientations), and the spatial relative descriptions used herein will be interpreted accordingly.

[0091] Furthermore, it should be noted that the use of terms such as "first" and "second" to define components is merely for the purpose of distinguishing the corresponding components. Unless otherwise stated, the above terms have no special meaning and therefore cannot be construed as limiting the scope of protection of this application.

[0092] The above description is merely a preferred embodiment of the present invention and is not intended to limit the invention. Various modifications and variations can be made to the present invention by those skilled in the art. Any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of the present invention should be included within the scope of protection of the present invention.

Claims

1. A gun positioning and management system, characterized in that, include: An electronic tag, used to be installed on a firearm, contains electronic firearm registration information; The locator and backend data management platform include a reader module, a satellite positioning module, a motion state detection module, an alarm module, a control module, and a communication module. The reader module, the satellite positioning module, the motion state detection module, and the alarm module are all signal-connected to the control module, and the control module is signal-connected to the communication module. The reader module is used to identify the electronic gun certificate information, the satellite positioning module is used to obtain the location information of the locator, and the motion state detection module is used to detect the motion state of the locator. The control module determines whether to issue an alarm control command based on the information detected by the reader module and / or the satellite positioning module and / or the motion state detection module. When the control module determines to issue an alarm control command, the control module controls the alarm module to issue an alarm signal; and / or, When the control module determines to issue an alarm control command, the control module transmits the alarm control command to the background data management platform through the communication module, and issues the alarm command through the background data management platform.

2. The gun positioning and management system according to claim 1, characterized in that, The reader module is used to identify the electronic gun certificate information within a preset distance range; When the reader module identifies the electronic gun certificate information within the preset distance range, the control module determines that the firearm is within a controllable range; When the reader module fails to identify the electronic gun certificate information within the preset distance range, the control module controls the alarm module to issue a first alarm signal; and / or, the background data management platform issues a first alarm command.

3. The gun positioning and management system according to claim 1, characterized in that, When the satellite positioning module detects that the locator is within a preset activity range, and the motion state detection module detects that the locator's position has not changed within a predetermined time period, the control module controls the alarm module to issue a second alarm signal; and / or, the background data management platform issues a second alarm command.

4. The gun positioning and management system according to claim 1, characterized in that, When the satellite positioning module detects that the locator has exceeded a preset activity range, the control module controls the alarm module to issue a third alarm signal; and / or, When the satellite positioning module detects that the locator has exceeded the preset activity range, the background data management platform issues a third alarm command and adjusts the preset activity range through the background data management platform.

5. The gun positioning management system according to claim 1, characterized in that, The gun positioning and management system also includes: The trajectory mapping module is connected to the background data management platform and is used to determine the motion trajectory of the locator based on the position information of the satellite positioning module. The map data storage module is connected to the background data management platform by a signal. The map data storage module is used to obtain the corresponding path planning information based on the location information of the satellite positioning module. The trajectory prediction module is connected to both the trajectory mapping module and the map data storage module. The trajectory prediction module compares the movement trajectory of the locator determined by the trajectory mapping module with the path planning information obtained by the map data storage module to plan the optimal path.

6. The gun positioning and management system according to claim 5, characterized in that, The gun positioning management system further includes an information acquisition module, which is used to acquire the communication contact information of the communication device of the staff member bound to the locator. The information acquisition module is signal-connected to the trajectory prediction module. The communication module is signal-connected to the information acquisition module and is used to transmit the alarm control command issued by the control module and / or the optimal path to the staff member's communication device. And / or, the communication module is a 4G private network module.

7. The gun positioning and management system according to claim 1, characterized in that, When the motion state detection module detects that the locator is stationary for a first preset time period, the control module controls the satellite positioning module to be in a silent state; when the motion state detection module detects that the locator is in motion or that the locator is not stationary for the first preset time period, the control module controls the satellite positioning module to be in an active state; and / or, When the reader module recognizes the electronic gun certificate information within a preset working frequency, the control module controls the reader module to reduce the working frequency; when the reader module does not recognize the electronic gun certificate information within the preset working frequency, the control module controls the reader module to maintain the current working frequency or increase the working frequency; and / or, When the motion state detection module detects that the locator is stationary within a second preset time period, the control module controls the communication module to reduce its operating frequency; when the motion state detection module detects that the locator is not stationary within the second preset time period, the control module controls the communication module to maintain the current operating frequency or increase its operating frequency.

8. The gun positioning and management system according to claim 1, characterized in that, The locator is linked to the electronic tag via radio frequency communication; and / or, The electronic tag contains projectile count information. The reader module is used to acquire the projectile count information. The communication module transmits the projectile count information and the corresponding locator location information to the background data management platform. The background data management platform then sends the projectile count information and the corresponding locator location information to the communication module of the locator that is active within a preset activity range.

9. The gun positioning and management system according to claim 1, characterized in that, The locator also includes: An information storage module, which is signal-connected to the reader module, the alarm module, the control module, and the satellite positioning module, is used to store information from the reader module, the alarm module, and the satellite positioning module; and / or, The alarm module includes at least one of an alarm light, a sounder, and an alarm information sending unit.

10. The gun positioning and management system according to claim 1, characterized in that, The locator also includes: A communication interface is provided for communication with the gun cabinet management platform; when the communication interface is connected to the gun cabinet management platform, the control module controls both the reader module and the alarm module to be powered off; and / or, The device includes a charging interface, a power detection module, and a battery module. The charging interface is used for electrical connection with a charger. The power detection module is connected to the battery module and is used to detect the charging level of the battery module. When the power detection module detects that the battery module is fully charged, it controls the charging interface to disconnect from the charger. When the power detection module detects that the charging level of the battery module is lower than a preset power value, it controls the charging interface to connect to the charger.