Anti_Sleep_Alarm_Project_Presentation.pptx

College Logo and Project Title COLLEGE NAME (IN BOLD) DEPARTMENT OF CIVIL ENGINEERING PROJECT TITLE: ANTI-SLEEP ALARM

TEAM INFORMATION SR NO | UIN / ROLL NUMBER | NAME 1 | | 2 | | 3 | | 4 | |

Introduction of Title Introduction: The Anti-Sleep Alarm is a safety device designed to keep drivers or workers awake and alert by preventing drowsiness. It detects fatigue through head movements or eye closure and triggers an alarm or vibration to wake the user. Objectives: 1. To prevent road accidents caused by sleepiness or fatigue. 2. To improve alertness during driving or working. 3. To develop a compact, affordable, and efficient alerting device. 4. To promote the use of safety-oriented electronic systems.

Significance of the Project The Anti-Sleep Alarm plays a crucial role in enhancing road safety and preventing accidents. It serves as a supportive device for drivers during long journeys or night shifts. Importance in Civil Engineering: In the field of civil engineering, road safety and transportation management are key areas. This project aligns with the goal of reducing traffic accidents and ensuring safer infrastructure usage. Real-World Applications: - Long-distance truck and bus drivers - Highway patrol and transport officers - Industrial machine operators and night-shift workers - Railway and aviation personnel Potential Beneficiaries: - Transportation departments - Logistics and delivery companies - Public safety agencies - Individual commuters Advantages Over Existing Solutions: - Low cost and easy to use - Portable and lightweight design - Quick response to drowsiness detection - Can be integrated with vehicles or helmets

Planning for Semester II Detailed Cost Analysis: Component | Specification | Quantity | Estimated Cost (₹) Microcontroller (Arduino Nano) | ATmega328P | 1 | 400 Tilt Sensor / IR Sensor | Head movement detection | 1 | 150 Buzzer | 5V | 1 | 50 Power Supply / Battery | 9V | 1 | 100 Casing Material | Plastic | 1 | 200 Total Estimated Cost: ₹900 System Architecture: Sensor → Microcontroller → Alarm/Buzzer Timeline of Tasks: Week 1–2: Component procurement and testing Week 3–4: Circuit design and connections Week 5–6: Programming and calibration Week 7–8: Assembly and final testing Week 9–10: Report preparation and presentation