Top 10 Easy Electronics Projects using NE555 Timer IC for Beginners

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Introduction

The 555 timer IC is one of the most useful Integrated circuits, utilized in various electronic projects. It’s a low-cost, widely used precision timing device that is used as a basic timer to create single pulses or large time delays, or as a relaxation, oscillator to generate a string of stabilized waveforms with duty cycles ranging from 50 to 100%. Since its internal circuitry includes a voltage divider network; made up of three 5K resistors, thus the name is 555. This IC may be used to produce precise time delays and oscillations. So, here in this article, we will discuss the Top 10 Easy Electronics Projects using NE555 Timer IC for Beginners.

(1) The Servo Controller

Hardware Required

S.noComponentValueQty
1.ICNE555 Timer1
2.Transistor BC5471
3.SW forward, Reverse 1,1
4.Capacitor10μF, 100μF1,1
5.Resister10KΩ, 36KΩ, 68KΩ 220Ω1,1,1,1
6.Battery9V1
7.3-Pin, 2-Pin Connector1,1

Circuit Diagram

servo-motor-driver-circuit-diagram-schematic

Working Explanation

In this Servo Motor Driver Circuit, we use IC 555 as an astable multivibrator and it generates the pulses at the output with two diverse duration. The pulse time of the output of the 555 timer IC depends on the timing resistor and Capacitor wired into the circuit.
When the switch SW1 is closed, the 555 clock IC generates a long-duration pulse, and the servo rotates in the clockwise direction And, when the switch SW2 gets closed, the 555 clock IC produces a short-duration high pulse and the servomotor rotates antilock wise. Thus, this is how the circuit works.

(2) LED Flashing Controller

Hardware Required

SrComponentsQty
1IC 555 Timer1
2LED Red, Green1,1
3Capacitor 1uF/ 16v1
4Resister 330Ω, 1KΩ, 100KΩ1,1
5Battery 9V1
62-Pin Connector1

Circuit Diagram

simple-led-flasher-circuit-diagram-schematic

Working Explanation

When light falls on the exterior side of the Light Dependent Resistor, the circuit flashes and makes a sound. The 555 timer IC, which is wired into the circuit as an astable multivibrator, is an important aspect of the circuit. As a darkness sensor, an LDR is employed. The circuit is controlled by a 10k variable resistor, which stimulates the alarm at the required amount of darkness. A speaker with an impedance of 8 ohms is connected to a capacitor with a capacitance of 4.7 microfarads and generates sound as an output. The frequency of the sound can be modified by changing the value of a 0.05 microfarad capacitor. The circuit works with a DC voltage range of 9 to 12 volts.

(3) Clap ON/OFF Switch

Hardware Required

SrComponentsQty
1IC 5551
2Condenser Mic4
3IC 74741
4Relay 9V4
5Transistor BC547 NPN 2
6Diode 1N40071
7Capacitor 10μF/16V, 0.01μF1,1
8Resistor 33KΩ, 1KΩ, 100KΩ1,1,1
99V Battery1
102-Pin Connector1

Circuit Diagram

Clap-ON-Clap-OFF-Switch-Using-555-circuit-diagram-schematic

Working Explanation

This Clap ON Clap OFF Switch consists of two stages. The first one is the detecting stage having a Condenser microphone and 555 timer IC which is configured as a monostable multivibrator The output from the microphone is given to the triggered input pin of the timer IC. In the second stage, the output from the timer IC is given to the clock input of the D flip flop. In other words, you can say that the timer Ic s providing a clock to flip-flop IC. The D flip flop recognizes a positive edge of the pulse and changes its state accordingly. Output from the flip flop is given at the base of the transistor which drives the relay.

When you clap near the condenser microphone, it generates some spike which will trigger the timer IC, and hence Ic generates a mono pulse which is taken by flip flop IC. The flip flop detects the positive edge in the pulse and changes its state to ON or OFF depending on the current state.

(4) The Brightness Sensor

Hardware Required

SrComponentsQty
1LDR1
4Capacitor (0.05uf, 4.7uf)1
5Potentiometer 10KΩ1
6speaker1
7Resistor 1k, 1.2k, 47k1, 1, 1
8555 Timer IC1
99V battery1

Circuit Diagram

Brightness Sensor_Diagram-Schematic

Working Explanation

When light falls on the exterior side of the Light Dependent Resistor, the circuit of light-actuated alarm employing 555 timers IC makes a sound (LDR). The 555 timer IC, which is attached to the circuit as an astable multivibrator, is an important aspect of the circuit. As a darkness sensor, an LDR is employed. The circuit is controlled by a 10k variable resistor, which stimulates the alarm at the required amount of darkness. A speaker with an impedance of 8 ohms is connected to a capacitor with a capacitance of 4.7 microfarads and generates sound as an output. The frequency of the sound may be modified by changing the value of a 0.05 microfarad capacitor. The circuit works with a DC voltage range of 9 to 12 volts.

(5) Timer Alarm Circuit

Hardware Required

SrComponentsQty
1IC 5551
2Buzzer1
3Switch6
4Electrolysis Capacitor 470uF1
5Capacitor 0.1uF1
6Resistor 100Ω, 20KΩ, 500KΩ, 1MΩ, 2.2MΩ, 1.5MΩ1,1,1,1,1,1
7Switch1
8Lithium-Ion Battery1

Circuit Diagram

Simple-Timer-Alarm-Circuit-using-IC-555-diagram-schematic

Working Explanation

In this Simple Timer Alarm Circuit, timer IC 555 is the major circuit component with few other components which are easily available, A 9V battery is used as the supply, and you can also create your own power supply by using a step-down transformer and Bridge Rectifier circuit. We connected the buzzer at the output pin of the timer IC. The start button is connected at pin 2 and through R2 Resistor. The circuit has a different range of Resistors for various timing ranges. You can turn ON this circuit by closing Switch S1. Choose the timer range by closing the switches S3, S4, S5, or S6 and then press the start switch s2 and then wait. On the output side, the buzzer will give the sound depending on the timing range.

(6) The Dark Sensor

Hardware Required

SrComponentsQty
1LDR (Any size)1
2IC 555 Timer1
3piezo buzzer1
4Potentiometer 1MΩ1
5Capacitor 1uF/25V, 0.01uF1,1
6Resistor 2.2KΩ, 10KΩ1,1
7Connecting wires
8Battery 9V1
92-Pin Connector1

Circuit Diagram

dark-detector-circuit-using-555-timer_Diagram-Schematic

Working Explanation

The 555 timer IC serves as an astable multivibrator circuit in this Darkness detection circuit. The circuit has a variable resistor that allows us to adjust the sensitivity. There is no current flow across the circuit when a continuous light falls on the LDR. The LDR senses the darkness and lowers its resistance if something happens between the light and the LDR. The electricity then flows through the circuit. The buzzer beeps as a result.

(7) DC Speed Controller

Hardware Required

SrComponentsQty
1 IC 555 Timer2
2Transistor IRF 5401,1,1
3Motor1
4Diode 1N40071
5Potentiometer 100K1
6capacitor 1000uF, Ceramic Capacitor 0.47uF1,1
7Register 10K, 47K, 560 Ohm1,1,1
8Battery 12v1

Circuit Diagram

DC Speed Controller_Diagram-Schematic

Working Explanation

In this DC motor speed control using IC 555, when we give an input supply of 12V to the circuit, the 555 timer IC generates the pulses at the output pin 3. The pulses depend on the potentiometer wired into the circuit. This output pulse from IC controls the MOSFET connected in the circuit as the output is given the base of the MOSFET which is then wired with the motor to control the speed. Hence, the speed can be controlled or varied by a potentiometer in the circuit.

(8) Touch ON OFF Switch

Hardware Required

SrComponentsQty
1Touch plate (refer to text)1
2IC 555 Timer1
3LED1
5Capacitor 10uF/25V, 0.01uF1,1
6Resistor 100KΩ, 470Ω1,1
7Connecting wires
8Battery 61
92-Pin Connector1

Circuit Diagram

touch-switch-circuit-using-ic-555-diagram-schematic

Working Explanation

The NE555 IC is used to create pulses in this circuit hence, works as a monostable multivibrator. Human contact is detected by a touch plate. When you place your finger on the touch plate, the signal is received by an IC’s trigger pin, which generates a mono pulse on the output side. Keep in mind that the pulse is determined by the timing capacitor c1 and the resistor R1. A LED is linked to the output side, which turns on when the pulse is received.

(9) LED Dimmer Circuit

Hardware Required

SrComponentsQty
1NE555 Timer IC1
2IRFZ441
3Powerful LED1
4Potentiometer (10-50k)1
51n4007 Diode2
6Resistor 1k2
7Ceramic Capacitor 100nF ,10nf1,1
8

Circuit Diagram

LED-Dimmer-Circuit

Working Explanation

The 555 timer acts as an astable multivibrator in this LED Dimmer Circuit, generating PWM pulses. Timing components such as resistors, potentiometers, and capacitors are included in the circuit. The potentiometer controls the duty cycle of the PWM signal. When the duty cycle is high, the light intensity is higher; when the duty cycle is low, the light intensity is lower. The diodes are utilized at the trigger pin to bypass the cycle of a wired potentiometer during IC charging in astable mode, as well as to control the constant frequency regardless of the duty cycle. MOSFETs are linked to the output of an IC to power the bright LED.

(10) LED Chaser Circuit

Hardware Required

S.noComponentQty
1CD4017 Decade Counter IC1
2PCB board for circuit1
3NE555 Timer IC1
4Potentiometer 1
5 power jack1
6Capacitors (1uF, 0.01uF)1, 1
7Resistors (10K, 680 ohms)1, 2
89V Battery1
9 LEDs11

Circuit Diagram

Circular LED Chaser Circuit_Diagram-Schematic

Working Explanation

In this Circuit using 555 and 4017, the clock input of the CD4017 decade counter IC is wired to the NE555 timer. The timer IC provides the decade counter’s CLK input with square wave input. Each pin on the CD4017 connects to an LED. By default, the ic’s output pin is high while it turned the remaining pins off. When the clock input pin of the 4017 IC detects a voltage rise from low to high, it turned the current output off and the next consecutive output gets turned on.

This output change, which appears to be the LEDs chasing each other, continues until it reached the last LED, at which point the output is reset to the first LED.