Majlesi Journal of Electrical Engineering ECG Arrhythmia Classification based on Convolutional Autoencoders and Transfer Learning Volume 16 (2022) Issue 3, September 2022 2024 02 11 ECG Arrhythmia Classification based on Convolutional Autoencoders and Transfer Learning 10.30486/mjee.2022.696505 EN Rasool Muayad Obaidi College of MLT, Ahl Al Bayt University, Kerbala, Iraq Riam Abdul Sattar Al Farahidi University / College of Law/ Iraq Mayada Abd Al-Manara College For Medical Sciences, Maysan, Iraq Inas Amjed Almani Department of Computer Technology Engineering, Al-Hadba University College, Iraq Tawfeeq Alghazali College of Media, Department of Journalism, The Islamic University in Najaf, Najaf, Iraq Saad Ghazi Talib Law Department, Al-Mustaqbal University College, Babylon, Iraq Muneam Hussein Ali Al-Nisour University College, Iraq Mohammed Q. Mohammed Al-Esraa University College, Baghdad, Iraq Tuqaa Abid Mohammad Department of Dentistry, Al-Zahrawi University College, Karbala, Iraq Mariam Raheem Abdul-Sahib Medical device engineering, Ashur University College, Baghdad, Iraq Journal Article 2024 02 11 An Electrocardiogram (ECG) is a test that is done with the objective of monitoring the heart’s rhythm and electrical activity. It is conducted by attaching a specific type of sensor to the subject’s skin to detect the signals generated by the heartbeats. These signals can reveal significant information about the wellness of the subjects’ heart state, and cardiologists use them to detect abnormalities. Due to the prevalence of heart diseases amongst individuals around the globe, there is an urgent need to design computer-aided approaches to automatically analyze ECG signals. Recently, computer vision-based techniques have demonstrated remarkable performance in medical image analysis in a variety of applications and use cases. This paper proposes an approach based on Convolutional Autoencoders (CAEs) and Transfer Learning (TL). Our approach is an ensemble way of learning, the most useful features from both the signal itself, which is the input of the CAE, and the spectrogram version of the same signal, which is fed to a convolutional feature extractor named MobileNetV1. Based on the experiments conducted on a dataset collected from 3 well-known hospitals in Baghdad, Iraq, the proposed method claims good performance in classifying four types of problems in the ECG signals. Achieving an accuracy of 97.3% proves that our approach can be remarkably fruitful in situations where access to expert human resources is scarce.