AUTOMATIC LIGHT & DARK SENSING SYSTEM WITH MOSQUITO REPELLENT CIRCUIT
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The document presents a mini project report on an 'Automatic Light & Dark Sensing System with Mosquito Repellent Circuit,' completed by students Shahrukh Javed and Mohammed Hassan at T. John Institute of Technology. It details the project's components, design, functioning, and applications, including the use of a transistor and LDRs to automate light control, as well as generating ultrasonic sound to repel mosquitoes. The project aims to enhance practical understanding in electronics and communication engineering while effectively implementing a system that senses light and darkness.
AUTOMATIC LIGHT & DARK SENSING SYSTEM WITH MOSQUITO REPELLENT CIRCUIT
- 1. Page | 1 A Mini Project Report on AUTOMATIC LIGHT & DARK SENSING SYSTEM WITH MOSQUITO REPELLENT CIRCUIT Submitted to T JOHN INSTITUTE OF TECHNOLOGY Bangalore. Bachelor of Engineering In Electronics and Communication Engineering By Shahrukh Javed BEE141570 Mohammed Hassan M BEE141549 Session: 2016-2017 Date of submission 13th Oct 2016 UNDER THE ESTEEMED GUIDANCE OF PROF. BASAVANAGOUDA DEPARTMENT OF ECE. Department of Electronics and Communication Engineering T JOHN INSTITUTE OF TECHNOLOGY (Visvesvaraya Technological University) (Approved by AICTE, Affiliated to VTU & Accredited by NAAC) 86/3, Gottigere, Bannerghatta Road, Bangalore - 560083
- 2. Page | 2 PREFACE This project provides complete information on the topic “AUTOMATIC LIGHT & DARK SENSING SYSTEM WITH MOSQUITO REPELLENT CIRCUIT” and maximum efforts have been taken to make the project more comprehensive and lucid to understand. This project covers a variety of sub topics like basic information, its working, day to day uses in life and different aspects of mosquito repellent circuit. One may notice a perceptible change in written in an easy dialogue style engaging the readers constantly and included with more informatics comments. I assure you to go through this project thoroughly to know a bit more and facts about Light & Dark Sensing System.
- 3. Page | 3 Declaration I hereby declare that the project entitled “AUTOMATIC LIGHT & DARK SENSING SYSTEM WITH MOSQUITO REPELLENT CIRCUIT” submitted by us to T. John Institute of Technology, Visvesvaraya Technological University during the degree of Bachelor of Engineering in Electronics & Communication Engineering is a record of bonafide project work carried out by us under the guidance of Mr. Basavanagouda. I further declare that the work reported in this mini project has not been submitted & will not be submitted either in part or in full for award of any degree in this institute. SHAHRUKH JAVED MOHAMMED HASSAN M
- 4. Page | 4 Acknowledgement The satisfaction that accompanies the successful completion of the task would be put incomplete without the mention of the people who made it possible, whose constant guidance and encouragement crown all the efforts with success. It is my greatest pleasure to thank Dr. Arun Vikas Singh Head of Department of Electronics and Communication, T.John Institute of Technology for providing us heart full encouragement support and allowing us to work in such a resourceful lab of this esteemed institute & thereby fulfilling one of my dreams. I whole heartedly thank my project guide Mr. Basavanagouda (Asst. Professor Electronics & Communication Department) for his consistent guidance, expert academic and support throughout the project, without his great concepts & inspiration it would have been impossible. I’m very much thankful to Mr.Chethan for his help in the laboratory for practical guidance during this project. I thank my parents for their emotional and financial support which they provided during this project. We show gratitude to our Honourable Principal Dr. H.N Thippeswamy, for having provided all the facilities and support. I thank to all faculties who directly and indirectly helped us in the completion of this projects.
- 5. Page | 5 INTRODUCTION Here is my new simple Electronics project about Automatic Light & Dark sensing system with mosquito repellent circuit. It is a simple and powerful concept, which uses transistor (BC 547) as a switch to switch ON and OFF the light automatically & a Light Dependent Resistors (LDR) which senses the light, made from a piece of exposed semiconductor material i.e cadmium sulphide, that changes its electrical resistance from several thousand Ohms in the dark to only a few hundred Ohms, when light hits the device, the photons give electrons energy by creating hole-electron pairs in the material. This makes them jump into the conductive band and thereby conduct electricity. The circuit automatically switches ON lights when the light goes below the visible region & automatically switches OFF lights when light fall on it, by using a sensor which senses the light just like our eyes. Also, the circuit has a long response time requiring many seconds to respond to a change in the light intensity. Finally we designed a simple Light & Dark sensing along with mosquito repellent circuit which can produce ultrasound in the frequency range of 20 kHz to 38 kHz, which can scare away mosquitoes.
- 6. Page | 6 COMPONENTS USED SR.NO. COMPONENT NAME SPECIFICATION QUANTITY 1. INTEGRATED CIRCIUT NE555 IC 1 2. TRANSISTOR BC547 2 3. POTENTIOMETER 10K 1 4. LDR 1K 2 5. RESISTOR 220K Ω 750 Ω 330 Ω 220 Ω 2 1 1 1 6. CAPACITOR 0.01 μF 2 7. BUZZER PIEZO MAGNETIC 1 1 8. LED RED GREEN 1 1 9. SWITCH ON/OFF 2 10. BATTERY 9V 1 Table 1. List of the Components Used.
- 7. Page | 7 MAJOR COMPONENT DESCRIPTION 1. NE555 IC Fig 1. Pin configuration of NE555 IC The 555 timer IC is an integrated circuit (chip) used in a variety of timer, pulse generation, and oscillator applications. The 555 can be used to provide time delays, as an oscillator, and as a flip-flop element. Derivatives provide up to four timing circuits in one package. These devices are precision timing circuits capable of producing accurate time delays or oscillation. In the time-delay or mono-stable mode of operation, the timed interval is controlled by a single external resistor and capacitor network. In the a-stable mode of operation, the frequency and duty cycle can be controlled independently with two external resistors and a single external capacitor. The threshold and trigger levels normally are two thirds and one-third, respectively, of VCC. These levels can be altered by use of the control-voltage terminal. When the trigger input falls below the trigger level, the flip-flop is set, and the output goes high. If the trigger input is above the trigger level and the threshold input is above the threshold level, the flip flop is reset and the output is low. The reset (RESET) input can override all other inputs and can be used to initiate a new timing cycle. When RESET goes low, the flip-flop is reset, and the output goes low. When the output is low, a low-impedance path is provided between discharge (DISCH) and ground. The output circuit is capable of sinking or sourcing current up to 200 mA. Operation is specified for supplies of 5 V to 15 V. With a 5-V supply, output levels are compatible with TTL inputs.
- 8. Page | 8 Pin description The connection of the pins for a DIP package is as follows: PIN NAME PURPOSE 1 GND Ground reference voltage, low level (0 V) 2 TRIG OUT will be high as long as the trigger is kept at low voltage. Output of the timer totally depends upon the amplitude of the external trigger voltage applied to this pin. 3 OUT This output is driven to approximately 1.7 V below +VCC, or to GND. 4 RESET A timing interval may be reset by driving this input to GND, but the timing does not begin again until RESET rises above approximately 0.7 volts. Overrides TRIG which overrides THR. 5 CTRL Provides "control" access to the internal voltage divider (by default, 2/3 VCC). 6 THR The timing (OUT high) interval ends when the voltage at THR ("threshold") is greater than that at CTRL (2/3 VCC if CTRL is open). 7 DIS Open collector output which may discharge a capacitor between intervals. In phase with output. 8 VCC Positive supply voltage, which is usually between 3 and 15 V depending on the variation. Table 2. Features 1. Timing From Microseconds to Hours 2. Astable or Monostable Operation 3. Adjustable Duty Cycle 4. TTL-Compatible Output Can Sink or Source Up to 200 mA Applications • Fingerprint Biometrics. • Iris Biometrics. • RFID Reader. • Pulse width modulation. • Precision timing and pulse generation.
- 9. Page | 9 2. LDR. LDR means light dependent resistance also called a photoresistor or a cadmium sulfide (CdS) cell is a light-controlled variable resistor.A photoresistor is made of a high resistance semiconductor. It is basically a photocell that works on the principle of photoconductivity.One of the most commonly used symbol is shown in the figure below. The arrow indicates light falling on it. If LDR placed in darkness, the resistance of LDR increases and when light falls on it, the resistance of LDR decreases and act as a conductor. Any LDR in the presence of light and darkness changes its resistance is depends on the different types of LDR. Fig 2. Light Dependent Resistor TYPICAL CONSTRUCTION. The snake like track shown above is the Cadmium Sulphide (CdS) film which also passes through the sides. On the top and bottom metal film are connected to the terminal leads & the sensitivity of a photo detector is the relationship between the light falling on the device and the resulting output signal. Thus it is designed in such a way as to provide maximum possible contact area with the two metal films, to provide free access to external light. Applications: Photoconductive cells are used in many different types of circuits and applications.
- 10. Page | 10 Analog Applications Digital Applications Camera Exposure Control. Automatic Headlight Dimmer. Photocopy Machines - density of toner. Night Light Control. Auto Slide Focus & Electronic Scales - dual cell. Oil Burner Flame Out. Densitometer & Colorimetric Test Equipment. Street Light Control. Automatic Gain Control – modulated light source. Absence / Presence (beam breaker) Automated Rear View Mirror. Position Sensor
- 11. Page | 11 CIRCUIT DIAGRAM Fig3. How The Circuit Works? Automatic Light & Dark sensing control system works like this: When it’s dark, the LDR has high resistance. This makes the voltage at the base of the transistor too low to turn the transistor ON. Therefore, no current will go from the collector to the emitter of the transistor. All the current will instead pass through the LDR and the potentiometer. When it’s light, the LDR has low resistance. This makes the voltage at the base of the transistor high enough to turn the transistor ON. Because the transistor is turned on, current flows through the transistor. It flows from the positive battery terminal, through resistor and the transistor down to the negative battery terminal. This makes the LED light up. Principle behind Mosquito Repellent Circuit: Human beings can hear sound in the range of 20 Hz to 20 kHz. Sound of any frequency above 20 kHz is termed as ultrasonic sound. Insects like mosquitoes have the feature of being able to hear this ultrasonic sound. In mosquitoes, this feature is attributed to the presence of sensory structures in their antennae. Usually ultrasound is transmitted by male mosquitoes and received by female mosquitoes. The ultrasound produces a stress on the antennae of the mosquitoes and repels them away.
- 12. Page | 12 Mosquito Repellent Circuit Operation: Once the switch is closed, the 555 timer gets the power supply. As per the inner circuit, initially the capacitor voltage will be zero and hence voltage at threshold and trigger pin will be zero. As the capacitor charges through resistors, at a certain point voltage at threshold pin is less than the capacitor voltage. This causes a change in timer output. The capacitor now starts discharging through resistor i.e. the discharge pin and continues so until the output voltage is back to the original. Thus the output signal is an oscillating signal with frequency 38 KHz. The output from this astable multivibrator circuit drives a 38 KHz piezo buzzer, producing ultrasound at regular repetitions. On varying the value of potentiometer the output frequency can also be varied.
- 13. Page | 13 Advantage Easy to operate & Fast response. Smaller in size. Low power consumption very small voltage for its operation. Sensor (LDR) is cheap and is readily available in many sizes and shapes. Disadvantages Highly inaccurate with a response time of about tens or hundreds of milliseconds. It requires a lot of frequency setting & It shows effect for lesser mosquito population. Applications: Light intensity Control for Street Lights Lighting Switch from Sunset to Sunrise Needs no manual operation for switching ON and OFF. Circuit can be used as a mosquito repellent.
- 14. Page | 14 CONCLUSION In this project we made an attempt to design Automatic Light & Dark sensing system with mosquito repellent circuit which can sense in light as well as in darkness. When in light- Light Sensor. Low Resistance –More Brightness to Switch on Led. When is dark- Dark Sensor. Low Resistance –More Darkness to Switch on Led. Our circuit has detected both the presence of Light and darkness. Mosquito Repellent. A simple circuit is designed which can produce ultrasound in the frequency range of 20 kHz to 38 kHz, which can scare away mosquitoes. Finally, the project has been successfully implemented & tested. It really persuades us to do more and more perhaps in better way in future. I am proud to express my delight as the project I embarked upon is successfully finished in such a short span. The project gave us more confidence that we will be able to put in practice, whatever the theoretical knowledge we gained during the course of study till now.