Design And Construction Of 20W Wireless Public Address System
The title “Design and Construction of a 20-watt Wireless Public Address System” encapsulates the intricate process of developing a cutting-edge audio system with a power output of 20 watts. This project involves the meticulous integration of various components, including transmitters, receivers, amplifiers, and speakers, to ensure seamless wireless communication and high-quality audio delivery. The emphasis on wireless functionality implies a reliance on advanced connectivity technologies, such as Bluetooth or Wi-Fi, enabling versatile applications in public spaces. The construction phase necessitates a keen understanding of electronic circuitry, signal processing, and acoustics, highlighting the project’s complexity. Engineers and enthusiasts undertaking this venture will grapple with challenges related to power efficiency, signal range, and audio fidelity. Overall, the pursuit of excellence in wireless public address system design demands a comprehensive grasp of engineering principles and a commitment to delivering a sophisticated audio solution for diverse public settings.
It has become inevitable that there would be communication and due to the inherent limitation of the human voice, the public address system came to being. A public address or “P.A SYSTEM” is an electronic amplification system with a mixer ,amplifier and loudspeakers, used to reinforce a given sound , e.g a person making a speech, pre-recorded music ,or message and distributing the sound throughout a venue . The voice signal is passed through a microphone , which converts the sound energy to electrical energy, the energy electrical signal being transmitted is been received and amplified by the amplifier circuit. The amplifier’s output is fed into the loudspeaker which converts the electrical energy back to the original form but amplified sound energy. This project is made up of the power supply unit, the pre-amplifier and power amplifier units, and the tone control unit. This system is capable of delivering 20W of electrical power into a 8 ohm load(loudspeaker).
Certification Page
Dedication
Acknowledgement
Abstract
Table of contents
List of Table
List of figures
CHAPTER ONE:
1.0 INTRODUCTION
1.1 Background Of The Study
1.2 Aims and Objectives
1.3 Justification
1.4 Scope of project
1.5 System block diagram
1.6 Project Work Organization
CHAPTER TWO:
2.0 LITERATURE REVIEW
2.1 Ancient medium of information transmission
2.2 Modern day medium Approach
2.2.1 Problems associated with earlier systems
2.2.2 Working principles of the modern systems
2.3 Public Address System
2.3.1 The transmitter system
2.3.2 The Receiver system
2.3.3 The Antenna
2.3.3.1 Functions of Antenna
2.3.4 The tone control and mixer stage
2.3.5 The audio amplifier
2.3.6 The loudspeaker
2.4 Modulation
2.4.1 Frequency modulation
CHAPTER THREE:
3.0 SYSTEM DESCRIPTION AND IMPLEMENTATION
3.1 Transistor power amplifier
3.2 MOSFET power amplifier
3.3 Bipolar junction transistor
3.4 Operational Amplifier
3.4.1 Class A amplifier
3.5 Implementation Method
CHAPTER FOUR:
4.0 CIRCUIT DESIGN AND ANALYSIS
4.1 Power Supply unit design
4.2 Transmitter design
4.3 Amplifier circuit design
4.4 Receiver principles
4.5 Demodulation
4.6 Transmitter circuitry
4.7 The input stage
4.8 Mixing stage
4.9 Audio power amplifier
CHAPTER FIVE:
5.0 CONSTRUCTION AND TESTING
5.1 The power supply
5.2 The output power amplifier
5.3 Dissipation of excessive heat
5.4 Entire circuit testing
5.5 Performance Evaluation
5.6 Packaging
CHAPTER SIX:
6.0 CONCLUSION AND RECOMMENDATION
6.1 Bill of Engineering measurement and Evaluation (BEME)
6.2 Problems Encountered and Solution
6.3 Audio feedback and prevention
6.5 Conclusion
6.6 Recommendation / Reference
INTRODUCTION
1.1 BACKGROUND OF THE STUDY
Fig 1: A picture of a modern wireless public address system
A public address system allows you to broadcast information to a large group of people, whether you are giving a speech or playing live or recorded music.
Public address systems typically consist of input sources, preamplifiers, control and monitoring equipment, and loudspeakers. Input sources refer to the microphones that provides a sound input for the system. These input sources are fed into the preamplifiers. The pre amplified signals are then passed into the audio power amplifiers.
These amplifiers will amplify the audio signals to an adequate speaker line level. In view of the above, one can now say that the public address system is an electronic amplification system used for communication in public areas.
Microphone is a device that converts sound waves into electrical waves. Some times colloquially called a micro mike is an acoustic-to-electric transducer or sensor that converts sound into an electrical signal. Microphones are used in many applications such as telephones, hearing aids, live and recorded audio engineering, in radio and television broadcasting and in computers for recording voice, and for non-acoustic purposes such as ultrasonic checking. The sensitive transducer element of a microphone is called its element. Since a wireless microphone is used in this project; a wireless microphone is one in which communication is not limited by a cable.
A transmitter is extremely important equipment and is housed in the broadcasting station. Its purpose is to produce radio waves for transmission into space. The important components of a transmitter are microphone, audio amplifiers, oscillator and modulator.
It usually sends its signal using a small FM radio transmitter to a nearby receiver connected to the sound system, but it can also use infrared light if the transmitter and receiver are within sign of each other. The transmitter are responsible for taking in the signal from the microphone, modulating it, and transmitting it to the receiver using radio waves.
Fig2:A transmitter circuit
The first transistor (Q1) is the pre-amplifier for the microphone, and you can omit this circuit if you don’t want to transmit the sound picked up by the mic, for example you can connect your mp3 player directly to C1. The core of this FM transmitter circuit is Q2, a modified Culprits oscillator that the frequency is determined by L1, C4, C6, and the transistor’s internal base-emitter capacitance. The antenna use 1/16 wave length to compromise between the efficiency and the size. If you want the microphone to be less sensitive, we can replace the R1 by a higher resistor, such as 10k or 22k, and this might overcome the feedback problem if you use this wireless microphone FM transmitter for a public address system
The receiver captures the radio waves sent out by the transmitter, demodulates the signal, amplifies it to an appropriate level, and sends it out to the audio mixer. A receiver is an electronic circuit that receives its input from an antenna, uses electronic filters to separate a wanted radio signal from all other signals
picked up by this antenna, amplifies it to a level suitable for further processing, and finally converts through demodulation and decoding the signal into a form usable for the consumer, such as sound, and digital data, etc.
Amplifier or simply amp is any device that changes, usually increases, the amplitude of a signal. The “signal” is usually voltage or current. Amplifier is a device for increasing the power of a signal. It does this by taking energy from a power supply and controlling the output to match the input signal shape but with larger amplitude. Routing the low-frequency parts of the signal to an amplifier can substantially improve the clarity of the overall sound reproduction.
In this project, the audio amplifier used is capable of delivering 20watts continuously. The term “power amplifier” is a relative term with respect to the amount of power delivered to the load and/or sourced by the supply circuit.
In general a power amplifier is designated as the last amplifier in a transmission chain (the output stage) and is the amplifier stage that typically requires most attention to power efficiency. Power amplifiers have also become lighter, smaller, more powerful and more efficient due to increasing use of Class A amplifiers, which offer significant weight and space savings as well as increased efficiency.
Power amplifier circuits (output stages) are classified as A, B, AB and C for analog designs, and class D and E for switching designs, based upon the conduction angle or angle of flow, Θ, of the input signal through the output amplifying device, that is, the portion of the input signal cycle during which the amplifying device conducts. The image of the conduction angle is derived from amplifying a sinusoidal signal. (If the device is always on, Θ = 360o.) In this project a class A amplifier is used because it offers low signal distortion.
Loudspeaker is an electro-acoustical transducer that converts an electrical signal to sound. A transducer that turns an electrical signal into sound waves is the functional opposite of a microphone.
Since a conventional speaker is constructed much like a dynamic microphone, (with a diaphragm, coil and magnet), speakers can actually work “in reverse” as microphones. The speaker pushes a medium in accord with the pulsations of an electrical signal, thus causing sound waves to propagate to where they can then be received by the ear. The loudspeaker used in this project is a load of 8 Ohms.
1.2 AIMS AND OBJECTIVES
Public speaking is the process of speaking to a group of people in a structured, deliberate manner intended to inform, influence, or entertain the audience. In public speaking, as in any form of communication, there are five basic elements, often
expressed as “who is saying what to whom using what medium with what effects?”(W.Kleitz;2005 pg134).
The major objective of this project is to design and construct a public address system with relatively unique operational characteristics that is capable of delivering 20 watts of electrical power into an 8 Ohms load (loudspeaker). This will be achieved with adequate tone controls and mixer stages so as to enable communication or reproduction of speech and recorded music in buildings and institutions.
1.3 JUSTIFICATION
Over the ages, science and technology has been developing with new inventions in various fields; including the increase in modifications on existing technology all gearing towards improving effectiveness and reliability of equipment and achieving to a great degree miniaturization and optimal cost.
This project is backed by my interest in the area of electronics and communication, and having been groomed to a great extent with introductions into the various fields of electrical and electronics engineering, with the knowledge in principles of telecommunications, telecommunication engineering,
basic electronics and lab practice. I chose to combine basic electronics and lab practice. I chose to combine all these ideas in embarking on this project to develop
a special system that utilizes all the above stated knowledge in one system; “the public address system”.
This system makes use of radio communication system, it utilizes radio frequency to achieve all its set objectives, like data communication in the operation of wireless communication between the transmitter and the receiver.
This system is intended to provide a fast and reliable means of communication in small venues such as school auditoriums, churches, and small bars.
1.4 SCOPE OF THE PROJECT
This system is for public address; it has an estimated power rating of 20watts. For power supplies, it uses a 220/12Vac transformer for the receiver, amplifier and loudspeaker units. It has a power On/Off button with volume control.
1.5 SYSTEM BLOCK DIAGRAM
Fig 3: Block diagram of a public address system
The system is made up of the transmitter which is incorporated in the microphone; and the receiver unit, the tone control and mixer unit, the audio amplifier unit and the loudspeaker.
POWER
SUPPLY
UNIT
RECEIVER UNIT
PRE-AMPLIFIER
CIRCUIT
TONE CONTROL AND MIXER CIRCUIT
AUDIO
AMPLIFIER UNIT CIRCUIT
LOUDSPEAKER
MICROPHONE
ANTENNA
Signal
1.6 PROJECT WORK ORGANISATION
The various stages involved in the development of this project have been properly put into six chapters to enhance comprehensive and concise reading. In this project thesis, the project is organized sequentially as follows:
Table 1 : Project work organization
INTRODUCTION
LITERATURE REVIEW
SYSTEM DESCRIPTION AND IMPLEMENTATION
CIRCUIT DESIGN AND ANALYSIS
CONSTRUCTION AND TESTING
CONCLUSION/RECOMMENDATION
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Design And Construction Of 20watts Wireless Public Address System:
Designing and constructing a 20-watt wireless public address system involves several components and steps. Here’s a high-level overview of the process:
1. System Requirements and Components:
Before you start designing, determine the specific requirements and components needed for your wireless public address system. In this case, you need a 20-watt amplifier, wireless microphone, speakers, power supply, and a wireless transmitter/receiver system.
2. Amplifier:
You’ll need a 20-watt amplifier to drive the speakers. You can purchase a pre-made amplifier or design your own using electronic components. Ensure it has the necessary inputs for connecting the wireless receiver and microphone.
3. Microphone:
Choose a wireless microphone that suits your needs. There are various types, including handheld, lapel, or headset microphones. Ensure it’s compatible with your wireless transmitter.
4. Speakers:
Select appropriate speakers based on the intended use and venue size. You may need one or more speakers, depending on coverage requirements. Make sure the speakers can handle the power output of your amplifier.
5. Wireless Transmitter/Receiver:
To transmit the audio wirelessly, you’ll need a wireless transmitter and receiver system. These can be purchased as a set, with compatible frequencies and range suitable for your application.
6. Power Supply:
Provide a stable power supply for the amplifier and wireless components. Depending on the system’s location, this could be a battery, AC power supply, or a combination of both.
7. Enclosure and Mounting:
Consider the physical design and enclosure for your system. Ensure it’s portable and durable, especially if it will be used outdoors. Mount the amplifier and wireless components securely.
8. Wiring and Connections:
Connect the microphone to the wireless transmitter and ensure proper synchronization. Connect the wireless receiver to the amplifier input. Connect the speakers to the amplifier’s output. Pay attention to cable quality and proper grounding.
9. Testing:
Before deploying the system, thoroughly test it to ensure all components work together seamlessly. Check the wireless range, audio quality, and power output. Adjust settings as needed.
10. Installation and Setup:
Install the system in the desired location. Ensure that speakers are strategically placed for optimal sound coverage. Set up any required signal processing (equalization, compression) to improve audio quality.
11. Maintenance:
Regularly maintain and check your system to ensure it continues to function correctly. Replace batteries, clean components, and make any necessary repairs promptly.
12. Compliance and Licensing:
Depending on your location and usage, you may need to comply with regulations related to wireless communication and public address systems. Check with local authorities if necessary.
13. User Training:
Provide training to users on how to operate the system safely and effectively.
14. Troubleshooting:
Create a troubleshooting guide for common issues and solutions that users can refer to in case of problems.
Ensure safety considerations are taken into account during the design and construction process, and always follow best practices for electrical and wireless equipment to prevent accidents or interference. If you’re not experienced with electronics or wireless technology, consider consulting with a professional or technician for assistance.