Development of roving security monitoring system using location-based technology/ Jasper Bryll N. Balana, Anna Marie L. Daracan, John Michael Franche, Clonjeck T. Nava, and Mark Angelo G. Quitiquit.--

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Balana, Jasper Bryll N [author]

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Material type: Text

TextPublication details: Manila: Technological University of the Philippines, 2024.Description: xiii, 113pages: 29cmContent type:

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BTH TK 5105.59 B35 2024

Dissertation note: College of Industrial Technology.-- Bachelor of engineering technology major in electronic communications technology: Technological University of the Philippines, 2024. Summary: This study focused on developing a Roving Security Monitoring System using location- based technology for real-time tracking and management of security personnel. By integrating GPS tracking and geofencing, the system ensures efficient emergency response. If security personnel are outside the designated geofence, an automated SMS alert notifies barangay security for prompt action. The system's hardware includes an ESP32 microcontroller utilizing IoT technology, a SIM800L V1 GSM module for SMS notifications, and a NEO M8N GPS module for precise location tracking. Arduino IDE is used for programming, while the front end is developed using HTML, CSS, and JavaScript. Firebase is the backend for user authentication, database management, and real-time updates, with OpenStreetMap (OSM) for digital mapping. The system was tested under different conditions. The GSM module’s response time at 1m, 2m, and 3m was 10.33, 14.33, and 10.66 seconds, respectively, suggesting that factors like signal interference affect performance more than distance. The GPS module maintained a stable 3-second response time at 10m and 15m, proving reliability over greater distances. However, in rainy weather, the GPS response time increased to 8.33 seconds, indicating that rain negatively affects performance. SMS alerts are only triggered when the vehicle exits the geofenced area, ensuring accurate perimeter detection. The GPS tracking system demonstrated realtime accuracy, effectively reflecting actual movement and validating its reliability. However, battery performance declined over time, supporting initial operation for 5 hours but requiring daily recharging to maintain functionality. The system was evaluated by fifty (50) evaluators composed of barangay security personnel, officials, electronics-related professionals, and experts. It was rated with an overall mean of 4.36 with a descriptive rating of "Very Good." This indicates that the prototype benefits the community by improving security efficiency, accountability, and response times, minimizing potential threats, and enhancing community safety.

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Holdings
Item type	Current library	Shelving location	Call number	Copy number	Status	Date due	Barcode
Bachelor's Thesis CIT	TUP Manila Library	Thesis Section-2nd floor	BTH TK 5105.59 B35 2024 (Browse shelf(Opens below))	c.1.	Not for loan		BTH0006286

Bachelor's thesis

College of Industrial Technology.-- Bachelor of engineering technology major in electronic communications technology: Technological University of the Philippines, 2024.

Includes bibliographic references and index.

This study focused on developing a Roving Security Monitoring System using location-
based technology for real-time tracking and management of security personnel. By

integrating GPS tracking and geofencing, the system ensures efficient emergency response.
If security personnel are outside the designated geofence, an automated SMS alert notifies
barangay security for prompt action. The system's hardware includes an ESP32
microcontroller utilizing IoT technology, a SIM800L V1 GSM module for SMS
notifications, and a NEO M8N GPS module for precise location tracking. Arduino IDE is
used for programming, while the front end is developed using HTML, CSS, and JavaScript.
Firebase is the backend for user authentication, database management, and real-time
updates, with OpenStreetMap (OSM) for digital mapping. The system was tested under
different conditions. The GSM module’s response time at 1m, 2m, and 3m was 10.33,
14.33, and 10.66 seconds, respectively, suggesting that factors like signal interference
affect performance more than distance. The GPS module maintained a stable 3-second
response time at 10m and 15m, proving reliability over greater distances. However, in rainy
weather, the GPS response time increased to 8.33 seconds, indicating that rain negatively
affects performance. SMS alerts are only triggered when the vehicle exits the geofenced
area, ensuring accurate perimeter detection. The GPS tracking system demonstrated
realtime accuracy, effectively reflecting actual movement and validating its reliability.
However, battery performance declined over time, supporting initial operation for 5 hours
but requiring daily recharging to maintain functionality. The system was evaluated by fifty
(50) evaluators composed of barangay security personnel, officials, electronics-related
professionals, and experts. It was rated with an overall mean of 4.36 with a descriptive
rating of "Very Good." This indicates that the prototype benefits the community by
improving security efficiency, accountability, and response times, minimizing potential
threats, and enhancing community safety.

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