We generally use an oscilloscope to depict the signal, calculate the time period of the signal and finally convert it to calculate the frequency of the signal. But, oscilloscopes are very expensive and everyone cannot afford it. Hence, a simple Digital Frequency Counter can be built which might come in handy to measure the frequency of a clock signal, for example. In this project, an Arduino based Digital Frequency Counter is designed to measure the frequency of an incoming signal.

Circuit Diagram

Figure Arduino Frequency Counter Circuit Diagram

Components

Arduino Part

Arduino UNO  [Buy Here] 16 X 2 LCD Display  [Buy Here] Prototyping Board Connecting wire Power Supply (adapter or battery)

Signal Generator Part

NE555 Timer IC 10 KΩ Potentiometer X 2 100 nF Capacitor (Code: 104) 1 µF / 16V Electrolytic Capacitor 5V Power Supply (12V is not suitable as it might damage Arduino board). Connecting wires Prototyping Board

Component Description

Arduino UNO: The ATmega 328P microcontroller based Arduino UNO is the main part of the project. It captures the time period of the incoming signal and calculates the frequency of the signal. 555 Timer IC: In this project, the 555 Timer IC is used as a pulse generator i.e. it works in astable mode. 16 X 2 LCD: The 16×2 LCD module is used to display the key information like welcome (or any custom) messages and the calculated frequency of the signal.

Circuit Design

The design of the Frequency Counter using Arduino UNO can be divided in to two parts: The Arduino part, where the processing of the signal’s information takes place and the Signal Generator part, where the signal whose frequency to be measured is generated.

Arduino Circuit

Arduino part of the project consists of Arduino UNO board and a 16 X 2 LCD Display. Pins 1 and 2 of the LCD (Vss and Vdd) are connected to ground and 5V supply respectively. Pin 3 (Vee), which is used to adjust the contrast of the display, is connected a Potentiometer. Pins 4 and 6 (RS and E) of the LCD are connected to digital I/O Pins 2 and 3 of the Arduino. Pin 5 (RW) of the LCD is connected to ground. Pins 11 to 14 (D4 to D7) i.e. the data pins of the LCD are connected to the digital I/O pins 4 to 7 of Arduino. Pins 15 and 16 of the LCD are supply pins of the backlight LEDs and are connected to ground and 5V (Pin 16 to 5V through a 1KΩ resistor) respectively.

Signal Generator Part

A 555 Timer is used to generate a pulse in this project. Hence, it is operated in Astable mode of operation. The connections for this mode are as follows. Pins 4 and 8 (Reset and Vcc) are connected to 5V Supply. Pin 1 (GND) is connected to ground. Pins 2 and 6 (Trigger and Threshold) are shorted. A 10KΩ Potentiometer is connected between the power supply and Pin 7 (Discharge). The wiper terminal of the potentiometer is connected to Pin 7. Similarly, another 10KΩ Potentiometer is connected between pins 7 and 6. This time, the wiper of the potentiometer is connected to Pin 6. A 100nF capacitor is connected between pin 6 and ground. By selecting this resistor, the frequency of the output signal, which can be taken from Pin 3 (Output), will be in the range of 480 Hz to 48 KHz. Optionally, a 1 µF capacitor can be connected, using which the frequency of the generated signal will be in the range of 50 Hz to 4.8 KHz.

Note: The power supply to the signal generator circuit should be only 5V. This is because, the voltage of the generated pulse will be same as that of the input voltage and the Arduino UNO board (or ATmega 328p microcontroller to be precise) can tolerate a maximum of 5.5V at its input pins.

Working Principle of the Project

The aim of the project is to design a simple digital frequency counter circuit using Arduino UNO and 555 Timer IC. The working of the project is very simple and is explained here. As mentioned earlier, the 555 Timer IC is configured to operate in Astable mode. Hence, the output of the 555 Timer IC (or rather the signal generator circuit) is a pulse with variable frequency (varied using potentiometer). This pulse is given as input signal to the Arduino UNO at one of its digital I/O pins. In the Arduino, we make use of a function called “pulseIn ();” The function pulseIn can be used to read either LOW or HIGH pulse on a digital I/O pin and returns the length of the pulse in microseconds. For example, if the pulseIn function is used to read a HIGH pulse on a pin, it waits for the pin to go HIGH. Once the pin goes HIGH, it starts the timer and runs until the pin goes LOW. The duration (in microseconds) of this HIGH pulse is then returned. In our project, we are calculating the duration of the HIGH pulse and LOW pulse and by adding them together, we get the period of the input signal. Inverse of this value gives the frequency of the signal which is displayed on the LCD. Note:

As mentioned earlier, the range of frequency of the signal generated by the 555 Tier can be changed by changing the value of the capacitor. Arduino can only detect incoming pulses i.e. the incoming signal can be either square or rectangular. Not all test signals can be in the form of pulses. Hence, we can use a Schmitt Trigger to convert the any incoming to a pulse. Also note that the output of the Schmitt Trigger IC (74LS14) is an inverted signal of the input signal.

Applications

A simple frequency counter, using simple components is designed that can be used to measure the frequency of a pulse without the need of an oscilloscope. Multiple ranges of frequencies can be measured by selecting suitable components. Frequencies of all types of test signals can be calculated by adding a Schmitt Trigger between the generated signal and Arduino.

Project Images

Project Code

with regards hope u will reply soon int pulseHigh; // Integer variable to capture High time of the incoming pulse int pulseLow; // Integer variable to capture Low time of the incoming pulse float pulseTotal; // Float variable to capture Total time of the incoming pulse float frequency; // Calculated Frequency void setup() { // put your setup code here, to run once: Serial.begin(9600); } void loop() { pulseHigh = pulseIn(pulsePin, HIGH); pulseLow = pulseIn(pulsePin, LOW); pulseTotal = pulseHigh + pulseLow; // Time period of the pulse in microseconds frequency = 1000000 / pulseTotal; // Frequency in Hertz (Hz) Serial.print(frequency); Serial.println(" Hz"); delay(500); } I went ahead and created the LCD screen hardware output then the signal generating hardware and it worked like a charm, except the sign on frequency is negative. Would that be a hardware issue or software issue? Any tips on figuring that out would be helpful. How can I use an antenna to receive the signal. I want to check a signal from a 433 MHz remote. Thank you. Comment * Name * Email * Website

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