Projects
In this project I used the Linux operating system to admeinister a corparate enviroment including adding and removing users, assigning privileges to files and directories, and running common Linux commands
In this Project I've created a Multiple Traffic Light Controller with a Cross Walk and an Emergency Buzzer with secured IoT Control via Web
This final course project is an assembly of all the projects that were completed in
the Fundamentals of Information System Security (SEC 285) course that I took
during the May/June 2025 session at DeVry University. These projects helped me
understand many things, including how firewall is used to protect enterprise computing
resources from attacks, how to create the Bring Your Own Device (BYOD) security
policy, the security controls to protect enterprise computing resources, the three
vulnerability assessment tools and the technical and administrative controls using
encryption. While completing the Module 2 Course Project, I learned that the
secure file management is implemented to mitigate risks to enterprise data assets.
In the Module Four Course Project the BYOD security policy that I created was for
ABC Corporation based on a SANS security policy template. Finally, the multi factor
authentication (MFA) is a very useful tool that was introduced in the Module Five Course
Project as well as other useful information.
This project for Everyday Physics (TECH204) applied the scientific method to real-world physics experiments by combining hardware, sensors, programming, and data analysis. The goal was to strengthen problem-solving, technical, and analytical skills while demonstrating key physical principles.
The project was divided into six parts, each building on the previous, ultimately forming a complete scientific experiment. Students used Internet of Things (IoT)-related sensors and microcontrollers to collect data, analyze results, and compare them to theoretical physics models.
Core Components & Sensors Studied:
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Ultrasonic Sensor (HC-SR04): Used to measure distances based on the travel time of sound waves.
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Rotary Encoder (KY-040): Measured angular motion and translated rotation into digital signals.
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Hall Effect Sensor (ESP32): Detected magnetic fields and measured changes in magnetic field strength.
Key Experiments & Results:
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Measured the speed of sound, obtaining ~335 m/s (close to the actual 343 m/s).
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Calculated gravitational acceleration, finding an experimental value of 6.588 m/s² vs. the theoretical 9.8 m/s² (about 32% difference due to friction, air resistance, or timing errors).
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Analyzed mechanical energy conservation, showing conversion between potential and kinetic energy with total energy decreasing slightly due to non-conservative forces.
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Validated the precision of rotary encoders for measuring distance, with small percent differences (3.75–6.5%) compared to ruler measurements.
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Examined magnetic field strength variations using the Hall Effect sensor, confirming the expected relationship between distance and field intensity.
This project demonstrates my understanding and ability to Create and Test SSL/TLS Files, Creating and Testing Snort Rules, Linux Processes, Process Hacker, Process Monitor, and Time-Based Access.