In this project, I’ll show how to design a Digital Voltmeter using 8051 Microcontroller and also explain its working. A voltmeter is a measuring instrument, used to measure the voltage difference between two points in an electrical network. Generally, there are two types of voltmeters – one is analog voltmeter and the other one is a digital voltmeter.

In analog voltmeter, a pointer moves on the scale to represent the voltage. Digital voltmeter directly displays the voltage in digits with the help of analog to digital converter. This article explains to you how to design a digital voltmeter in two methods 1) using 8051 microcontroller and 2)the other using IC L7017.

Digital Voltmeter using 8051 Microcontroller and Voltage Sensor Image 1

Digital Voltmeter using 8051 Microcontroller 

This project measures the input voltage from 0V to 25V. Here, the input voltage should be DC voltage to get the accurate output on LCD. If you apply AC voltage as input, then will see the continuous running numbers on LCD as AC varies continuously.

The major components in this project are 8051 microcontrollers, a Voltage Sensor Module and an ADC IC ADC0804. In this project, we use analog to digital conversion process to display the voltage.

Analog to Digital Conversion

In the real world, mostly we find analog data. To manipulate this data using digital systems, we need to convert analog data to digital, so that microprocessor or microcontroller is able to understand and manipulate the data.

Interfacing of Physical Quantity to Digital System

Interfacing of Physical Quantity to Digital System

Transducer: Transducer or sensor is used to convert the physical quantity to electrical energy. Light-dependent resistor, temperature sensor, humidity sensor, gas sensor etc. are examples of transducers.

ADC (Analog to Digital Converter): ADC converts the input electrical voltage to Digital value.

Digital System: this system reads input digital data and displays the physical quantity on LCD for understanding purpose.

Here ADC IC generates the output digital value based on the input electrical voltage. The 8051 microcontroller reads this digital value and displays it on LCD.

Digital Voltmeter using 8051 Microcontroller Circuit Diagram

Digital Voltmeter using 8051 Microcontroller and Voltage Sensor Circuit DiagramCircuit Components

AT89C51 microcontroller

ADC0804 IC

25V Voltage Sensor

AT89C51 programming board

Variable resistor (to demonstrate the program)

DC Adapter or Battery

Digital Voltmeter Circuit Design using 8051 Microcontroller

In the above circuit, analog to digital converter IC data bits is connected to the PORT2. LCD data pins are connected to the POTR3 of controller and control pins RS and EN are connected to the P1.6 and P1.7 respectively.

ADC0804  

This is an 8 bit analog to digital converter. This IC uses a successive approximation method to convert analog values to digital. It can take only one analog data as input. The step size of this IC is varied by varying the reference voltage at pin9. If this pin is not connected, VCC will be the reference voltage.

For every 19.53mV, the rise in input voltage the output is incremented by 1 value when the step size is at 5V. The conversion time of this IC depends on the clock source.

ADC Features

0 to the 5V analog input voltage.

Built-in clock generator.

Differential analog inputs.

Adjustable reference voltage.

Below table shows the different step sizes for different reference voltages.

In the above circuit diagram, pin9 (Vref/2) is left open so that the input voltage span can be 0 to 5V.

Step size = Vref/(2 pow(n))

Where n is a resolution. For ADC0804 the resolution n=8. The digital output can be calculated using the formulae

Dout = Vin/stepsize.

Vin – analog input voltage

 For example, let the analog input voltage is 4V, then the digital output is Dout=4/19.53mV=204.

Steps to Convert the Analog Input to Digital

Read the ADC value from the PORT2.

#define dat P2

val=dat*0.02;

After multiplying by 100, you get a positive interger value of three digits. 

val1=val*100;

Separate individual numbers and print them on LCD including the decimal point.

temp=(((val1/100)%10)+48);

display(temp);

display(‘.’);

temp=(((val1/10)%10)+48);

display(temp);

temp=((val1%10)+48);

display(temp);

Voltage Sensor

The voltage sensor module is a simple voltage divider network that increases the analog input range of the ADC to about 25V.

Interfacing Voltage Sensor with Arduino Voltage Sensor Pins

Code

How does Digital Voltmeter Circuit work using 8051 Microcontroller?

Initially, burn the program to the at89c51 microcontroller.

Now give the connections as per the circuit diagram.

Connect a battery or any voltage source at the input of the voltage sensor.

Make sure that maximum analog input voltage should be less than 25V DC

Connect a digital multimeter at the Input terminals of the voltage sensor.

Now switch on the board supply.

Now observe both LCD and digital multimeter, both displays the same voltage (or very similar voltages).

If possible, try to slowly vary the analog input voltage. Now you can observe that both multimeter and LCD displays the same voltages so that we can say that voltmeter is working properly.

Switch off the board supply.

Digital Voltmeter using 8051 Microcontroller and Voltage Sensor Image 2

Digital Voltmeter Circuit Applications

This system is used to measure the voltage in low voltage applications.

Used to measure the toy batteries.

We can measure the physical quantities like temperature, humidity, gas etc. using this system with a little modification.

Digital Voltmeter Circuit Limitations

The input analog voltage range should be 0 to 5V.

Using this system we can measure only one analog input value at a time.

Digital Voltmeter Circuit using ICL7107

The voltmeter can also be designed without using any microcontroller. Here is the circuit of voltmeter using L7017 IC

Here we design an analog to digital converter working as a digital voltmeter using a low power three and a half digit A/D converter ICL7107 having internal 7 segment decoders, display drivers, a reference and a clock.

An advantage is this IC can directly drive non multiplexed seven segment display without any external decoding circuitry. The circuit can measure voltage in the range of 200mV to 2V with an interval of 0.001V.

Principle Behind the Circuit

This circuit is based on the principle of using ICL7107 as an analog to digital converter. The whole operation is divided into two phases- Analog to digital conversion and decoding.

Analog to digital conversion is done using the process of integrating and reference integrating. In other words, the input signal is first integrated to bring the output of the integrator to ramp signal and an opposite polarity reference voltage is then integrated to bring the output of integrator back to zero.

The resultant digital code obtained is then decoded using to display decoders to drive the display unit.

Digital Voltmeter Circuit Diagram using ICL7107

Circuit Diagram of Digital Voltmeter using ICL7107

How Design Digital Voltmeter Circuit?

Designing the circuit requires appropriate selection of the components as given below:

Selection of Oscillation Circuit Components:  For a typical oscillating frequency of 48 KHz, the oscillating resistor has been chosen to be about 100K and the capacitor about 100pF.

Reference Capacitor: The value of the reference capacitor is chosen to be between 0.1uF and 1uF. Here we choose a 0.5uF electrolyte capacitor.

Auto-zero Capacitor: The auto-zero capacitor is selected such that its value is between 0.01uF and 1uF. Here we select a 0.1uF capacitor.

Integrating Capacitor: The integrating capacitor forms an essential part of the integrating circuit. Its value is determined by the integration period t, optimum integration current I and integrated voltage Vint. For a time period of 83mSec, a current of 4uA and voltage of 2V, the value of the capacitor is found to be around 0.16uF. Here select a 0.22uF capacitor.

Integrating Resistor: The value of this resistor is given by the full-scale analog input voltage and the optimum integration current. We select a resistor of 500K for a full-scale input voltage of 2V.

How to Operate Digital Voltmeter Circuit?

The IC is powered by a dual supply of +/- 5V. Once the circuit is powered, the reference signal is set by adjusting the reference resistor. The reference voltage needs to be about half of the input voltage. The oscillating components – resistor and capacitor determine the oscillating or clock frequency of the device.

The reference capacitor is charged to the reference voltage. A feedback loop is then closed to charge the auto-zero capacitor such that is compensates for any fluctuations in voltages. Later the converter integrates the differential voltage at the input for a fixed time such that output of the integrator is a ramp signal.

A known reference voltage is then applied to the input of integrator and is allowed to ramp till the output of integrator becomes zero. The time taken for the output to return back to zero is proportional to the input signal and the digital reading is given as:

Display Count = (Vin/Vref)*1000.

The next process involves decoding the digital count to produce a seven segment compatible signal so as to drive the displays. The digital output is then displayed on the multiplexed 7-segment display.

Applications of Digital Voltmeter Circuit

This circuit can be used in digital multimeters to provide a digital reading of measured voltage.

It can be used to measure AC and DC voltages.

It can be used to measure physical quantities like pressure, temperature, stress using transducer circuit and signal conditioning circuit.

It can be used in applications where high accuracy and high resolution is required.

Limitations of Digital Voltmeter Circuit

It can measure voltages only up to a low range.

The IC used is a CMOS device and is highly static.

Difference in reference voltage for negative and positive input voltage can cause rollover error, i.e. a common mode error.

Using a full-scale negative input voltage of 2V can sometimes cause the output of the integrator to saturate.

Internal heating from the LED drivers can cause degradation in performance.

Reference temperature coefficient, internal chip dissipation, and package thermal resistance tend to increase the noise level.

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