AD8232 Heart Rate Monitor Leave a comment

Introduction

The AD8232 is a neat little chip used to measure the electrical activity of the heart. This electrical activity can be charted as an ECG or Electrocardiogram. Electrocardiography is used to help diagnose various heart conditions. Now for the disclaimer:

NOTE: This device is not intended to diagnose or treat any conditions.

Covered in this Tutorial

In this tutorial, we will go over the basics for getting your AD8232 Heart Rate Monitor up and running. First, an overview of the board and all its features will be presented. Then, we’ll show you how hook it up to your favorite microcontroller and how to create visual data using Processing.

Understanding the ECG

In general terms, lets look at what an ECG is representing and how we’re able to sense it. The ECG is separated into two basic Intervals, the PR Interval and the QT Interval, described below.

PR Interval

The PR interval is the initial wave generated by an electrical impulse traveling from the right atrium to the left. The right atrium is the first chamber to see an electrical impulse. This electrical impulse causes the chambers to “depolarize”. This forces it to contract and drain deoxygenated blood from both the Superior and Inferior vena cava into the right ventricle. As the electrical impulse travels across the top of the heart it then triggers the left atrium to contract. The left atrium is responsible for receiving newly oxygenated blood from the lungs into the left ventricle via the left and right pulmonary veins. The pulmonary veins are red in the diagram because they are carrying oxygenated blood. They are still called veins because veins carry blood towards the heart. Science!

QT Interval

The QT Interval is where things get really interesting. The QRS is a complex process that generates the signature “beep” in cardiac monitors. During QRS both ventricles begin to pump. The right ventricle begins to pump deoxygenated blood into the lungs through the left and right pulmonary arteries. The pulmonary arteries are blue in the diagram because they are carrying deoxygenated blood. They are still called arteries because arteries carry blood away the heart. Science, Again! The left ventricle is also beginning to pump freshly oxygenated blood through the aorta and into the rest of the body. After the initial contraction comes the ST segment. The ST segment is fairly quiet electrically as it is the time where the ventricles waiting to be “re-polarized”. Finally the T wave becomes present to actively “re-polarize”, or relax the ventricles. This relaxation phase resets the ventricles to be filled again by the atriums

Connecting the Hardware

In this guide, we’ll connect the AD8232 Breakout to an Arduino microcontroller. We will build a simple cardiac monitor that will allow you to measure the electrical activity of the heart in real time!

Pin Connections

The AD8232 Heart Rate Monitor breaks out nine connections from the IC. We traditionally call these connections “pins” because they come from the pins on the IC, but they are actually holes that you can solder wires or header pins to.

We’ll connect five of the nine pins on the board to your Arduino. The five pins you need are labeled GND3.3vOUTPUTLO-, and LO+.

Board Label Pin Function Arduino Connection
GND Ground GND
3.3v 3.3v Power Supply 3.3v
OUTPUT Output Signal A0
     
LO- Leads-off Detect – 11
     
LO+ Leads-off Detect + 10
     
SDN Shutdown Not used
     

Connecting Headers to the Board

You can use any method you’d like to make your connections to the board. For this example, we’ll solder on a five-pin length of male-male header strip and use a breadboard and jumpers to make our connections.

Follow the diagram below, to make necessary connections. The SDN pin is not used in this demo. Connecting this pin to ground or “LOW” on a digital pin will power down the chip. This is useful for low power applications.

Now that the electronics are complete, let’s look at sensor pad placement. It is recommended to snap the sensor pads on the leads before application to the body. The closer to the heart the pads are, the better the measurement. The cables are color coded to help identify proper placement.

 

Cable Color Signal
Black RA (Right Arm)
Blue LA (Left Arm)
Red RL (Right Leg)
   

 

Uploading the Sketch and Connecting with Processing

By this point, you should have the hardware connected and ready.

The example sketch can be found at the end of this tutorial. You can cut and paste the code straight from there.

Now that you have a sketch running, let’s get the processing sketch ready. The processing sketch will give you a visual output of what’s going on. The example processing sketch can be found after the code section. 

If the processing sketch does not work, you may need to modify the following line:

myPort = new Serial(this, Serial.list()[2], 9600);

You may need to change the parameter inside Serial.list()[N]. A List of available COM ports will appear in the lower portion of the sketch window. Remember that COM port selection begins at 0. Typically your Arduino will appear as the highest COM number if it is the only device connected to your computer.

If everything is working correctly, you should see a nice box pop up and start displaying the output signal.

If your subject decides to remove the sensors, the leads off detection will kick in and display a flat blue line.

Arduino Code

void setup() {

  // initialize the serial communication:

  Serial.begin(9600);

  pinMode(10, INPUT); // Setup for leads off detection LO +

  pinMode(11, INPUT); // Setup for leads off detection LO –

}

void loop() {

if((digitalRead(10) == 1)||(digitalRead(11) == 1)){

    Serial.println(‘!’);

  }

  else{

    // send the value of analog input 0:

      Serial.println(analogRead(A0));

  }

  //Wait for a bit to keep serial data from saturating

Processing Sketch
import processing.serial.*;
           
            Serial myPort;        // The serial port
            int xPos = 1;         // horizontal position of the graph
            float height_old = 0;
            float height_new = 0;
            float inByte = 0;
           
           
            void setup () {
              // set the window size:
              size(1000, 400);       
           

              // List all the available serial ports
              println(Serial.list());
              // Open whatever port is the one you’re using.
              myPort = new Serial(this, Serial.list()[2], 9600);
              // don’t generate a serialEvent() unless you get a newline character:
              myPort.bufferUntil(‘\n’);
              // set inital background:
              background(0xff);
            }
           
           
            void draw () {
              // everything happens in the serialEvent()
            }
           
           
            void serialEvent (Serial myPort) {
              // get the ASCII string:
              String inString = myPort.readStringUntil(‘\n’);
           
              if (inString != null) {
                // trim off any whitespace:
                inString = trim(inString);
           
                // If leads off detection is true notify with blue line
                if (inString.equals(“!”)) {
                  stroke(0, 0, 0xff); //Set stroke to blue ( R, G, B)
                  inByte = 512;  // middle of the ADC range (Flat Line)
                }
                // If the data is good let it through
                else {
                  stroke(0xff, 0, 0); //Set stroke to red ( R, G, B)
                  inByte = float(inString);
                 }
                
                 //Map and draw the line for new data point
                 inByte = map(inByte, 0, 1023, 0, height);
                 height_new = height – inByte;
                 line(xPos – 1, height_old, xPos, height_new);
                 height_old = height_new;
               
                  // at the edge of the screen, go back to the beginning:
                  if (xPos >= width) {
                    xPos = 0;
                    background(0xff);
                  }
                  else {
                    // increment the horizontal position:
                    xPos++;
                  }
               
              }
            }

The items used in this experiment
المواد المستخدمة في التجربة يمكنكم اضافتها الى سلة مشترياتكم مباشرة من هنا

Tips and Tricks

ECG’s are notoriously noisy. This is because you are measuring muscle activation. The further sensor pads are from the heart, the more muscle noise you will see. These are commonly referred to as “Motion Artifacts”. So here are some simple tips to improve the signal quality.

  • Keep sensor pads as close to the heart as you can.
  • Make sure the RA and LA sensor pads are on correct sides of the heart.
  • Try not to move too much while taking a measurement.
  • Try to use fresh pads for each measurement. The pads loose the ability to pass signals with multiple applications.
  • Prep and clean the area you plan to stick pads. This will help make a good connection (hair is not a good conductor).
  • You may have to adjust sensor placement for different individuals.

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