Microcontroller Based Heart Rate Meter System
In this project, the design and implementation of a portable microcontroller-based heart rate meter system are discussed, focusing on low cost, low power, portability, and ease of use for medical practitioners in developing countries. Using the AT89S52 microcontroller, the system can acquire, amplify, and interpret ECG signals to monitor cardiac conditions. Heart rate can be measured through the pulse method, and the system utilizes hardware tools such as the LM358 operational amplifier and light-dependent resistor. Benefits include low cost, reliability, user-friendliness, and portability.
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Presentation Transcript
GROUP MEMBERS SYED JUNAID HUSSAIN SHAH MUHAMMAD QASIM IRSHAD
PROJECT NAME Microcontroller Based Heart- Rate Meter
INTRODUCTION The design and implementation of a portable microcontroller based heart rate meter system is discussed in this project. The design considerations for this project are mostly influenced by the proposed users of the system. These users are medical practitioners in developing countries, who have very limited medical infrastructure. Hence, low cost, low power, portability, and ease of use are factors that are considered at every stage of the design. This system explores a low power microcontroller, the AT89S52, manufactured by Atmel Instruments for signal analysis. This is a compact system capable of acquisition, amplification, and interpretation of biological signals (ECG), as well as notification whenever cardiac conditions such as tachycardia and bradycardia are experienced.
Heart rate can be measured either by the ECG waveform the finger (pulse method). The blood flow into the finger (pulse method). The pulse method is simple and convenient. When blood flows during the systolic stroke of the heart into the body parts, the finger gets its blood via the radial artery on the arm. The blood flow into the finger can be sensed photo electrically. To count the heart beats, here we use a small light source on one side of the finger (thumb) and observe the change in light intensity on the other side. The blood flow causes variation in light intensity reaching the light- dependent resistor (LDR), which results in change in signal strength due to change in the resistance of the LDR.
HARDWARE TOOLS AT89S52 Microcontroller LM358 Operational amplifier Light dependent resistor Seven segment display or LCD DISPLAY Cathode ray oscilloscope
BLOCK DIAGRAM The block diagram of the microcontroller based heart- rate meter mainly contains the components as shown below
BENEFITS Low Cost Low power Consumption Reliability Easily accessible User Friendly Portability
After inserting the finger we will observe the heart rate in displays and by connecting the pin 3 of IC 1 to CRO we also observe the heart beat signal.
CONCLUSION CONCLUSION All in all, this project achieved a lot of its goals. The project implemented a low cost, low power, LCD heart rate display system using microcontroller technology. Lists of accomplishments include portability, reliability and analog to digital conversion and also the system is easily accessible.
FUTURE SCOPE The microcontroller based heart rate system designed in this project has a lot of advantages, but can also be improved on. There is a lot of improvement that can be made to the project that would result in a more reliable system as stated in the recommendations section.
Looking ahead, as microcontrollers get more and more advanced, there will be a shift from analog amplification to digital amplification. Biological signals from the electrodes can be fed directly into the microcontroller, where the front end. This will significantly reduce the surface area consumed by a circuit and would lead to a smaller, more compact, and portable system.
More work can be done in the processes leading to the acquisition of these small biological signals. There are many challenges that still pose big problems in the design of systems like this.
