Project Abstract

Abstract
The project involves designing and constructing an automated light system using a photo-sensitive switch. The system aims to provide energy-efficient lighting by automatically turning on and off based on the ambient light conditions. The design incorporates a photo-sensitive switch that detects changes in the light levels and triggers the light system accordingly. The system is intended for indoor use in spaces where natural light may vary throughout the day, such as offices, homes, and public buildings. The automated light system consists of a light source, a photo-sensitive switch, and a control circuit. The light source is a LED panel that provides bright and energy-efficient lighting. The photo-sensitive switch is a key component that detects the amount of light in the environment. When the light levels fall below a certain threshold, the switch signals the control circuit to turn on the LED light. Conversely, when sufficient natural light is available, the switch instructs the control circuit to turn off the artificial light source. The control circuit is designed to efficiently manage the operation of the light system. It includes a microcontroller that processes the signals from the photo-sensitive switch and controls the activation of the LED light. The circuit is programmed to ensure smooth transitions between natural and artificial lighting, providing a seamless lighting experience for the users. Additionally, the system incorporates safety features to prevent overheating and ensure reliable operation. The automated light system offers several benefits, including energy savings, convenience, and enhanced user experience. By automatically adjusting the lighting based on ambient conditions, the system reduces energy consumption and lowers electricity costs. The convenience of having lights that turn on and off on their own enhances user comfort and eliminates the need for manual intervention. Moreover, the system contributes to a more sustainable environment by promoting energy efficiency and reducing carbon footprint. Overall, the project demonstrates the feasibility and effectiveness of designing an automated light system using a photo-sensitive switch. The integration of technology and sensors enables the system to operate autonomously and provide efficient lighting solutions. The automated light system has the potential to be implemented in various indoor settings to enhance energy efficiency and user experience.

Project Overview

1.0. INTRODUCTION
1.1. GENERAL DESCRIPTION OF THE PROJECT

Industrial electronics has turned the whole world into a global village. One of the most indispensable aspects of these phenomena is automation, which forms the nucleus of the present day electronics technology. Considering the milestone, it was desired to make the choice of the project research on the design and implementation of an automatic fence light controller.
This electronics system is realized with a cadmium – sulphide photo-conductive cell which serves as the light sensor. The output of the light dependent resistor is fed into a delay circuit configured using an n RC- network. The output of the RC-network bases a Darlington pair transistor which drives an electromagnetic are interfaced. The overall circuit is powered by a 12 v d.c. unregulated power supply unit that properly filtered.
1.2. STATEMENT OF THE PROBLEM
This project work signifies a lot in industrial automation, telecom, computer electronics and ICT at large. It seeks to eliminate the stress, time and inconvenience associated with manual switching of security lights. It has a wide range of real-life applications basically in automation and can be used in surveillance system if properly modified. It can be used to illuminate farm settlement automate irrigation pumps in the farm usually in the night to scare away thieves and rodents to increase yield.
1.3. OBJECTIVES OF THE PROJECT
1. One of objectives of this project is to design and implement an electronic system capable and implement an electronics system capable of switching on lamps at twilight and switching off.
2. It is also aimed at an in depth study of random logic design and implementation.
3. This project is equally aimed at grounding the young engineers in engineering technical and scientific writings which cannot be over emphasized in engineering professional practice.
1.4. SCOPE OF THE PROJECT
This project is focused on designing and constructing of an automated light system using photo-sensitive switch. That is, to illuminate the case study in response to change in weather. The system comes on at twilight through the night and goes off at dawn all through the day. The project research work covers the following photosensitive devices like light dependent Resistor (L.D.R) which serves as the sensor. It x-rays the design calculations of the basic circuit parameter and other areas of applications of this system. It also lays great emphasis on passive and active components like Diode Resistors, capacitors Darlington pair transistors, electromagnetic relays, lamps and transformers.
1.5. OVERVIEW OF THE PROJECT
The high rate of technological advancement in industrial automation, security and control motivated me to embark on a project research work on design and implementation of automated light system using photosensitive switch. This electronics system is designs in five different modules all combined to form one functional unit. The first module is the sensor (light-dependent-resistor). Its output is conditioned by an RC-network (delay circuit) that forms the second module. The third module is the driver realized with Darlington pair transistor. The fourth module is the electromagnetic relay where the fifth and final module –load are interfaced. The result being a rugged, robost and easy – to – maintain system.
1.6. PROJECT REPORT ORGANISATION
This project is presented in six chapters to appropriately illustrate the steps involved in its design and implementation. Chapter one introduces the designs objectives, general introduces the design objectives, general description of the project and significances of the project. Chapter two is fundamentally the literature review and issues relating to its implementation. Chapter three confers the system methodology and analysis. Chapter four elaborates on the system design and analysis. Chapter five x-rays the implementation and testing. The sixth and last chapter summarizes the project theories conclusion and recommendations.