Abstract
The present work is oriented to the development and design of a system that allows to simplify the learning of the fundamentals of electrocardiography. The proposed system uses NI LabVIEW software and the Biomedical Toolkit to design an interface with graphic and descriptive elements of a cardiac biopotential that generates normal heartbeats and / or abnormalities in the heartbeat. The result is an alternative tool in the teaching-learning process for medical, biomedical or bioengineering students.
Keywords: Learning System, ECG, NI LabVIEW.

Resumen
El presente trabajo está orientado al desarrollo y diseño de un sistema que permita simplificar el aprendizaje de los fundamentos de electrocardiografía. El sistema propuesto utiliza el software NI LabVIEW y el Toolkit de Biomédica para diseñar una interfaz con elementos gráficos y descriptivos de un biopotencial cardiaco que genere latidos cardiacos normales y/o anormalidades en el latido cardiaco. El resultado es una herramienta alternativa en el proceso de enseñanza-aprendizaje para estudiantes de medicina, biomédica o bioingenierías.
Palabras Clave: Sistema de Aprendizaje, ECG, NI LabVIEW.

Woltjer H.H., Bogaard H.J., de Vries P.M., The technique of impedance cardiography, European Heart Journal, Volume 18, Issue 9, 1997.

Schookin, S. I., Zubenko, V. G., Beliaev, K. R., Morozov, A. A., & Yong, W. H. (1997). U.S. Patent No. 5,685,316. Washington, DC: U.S. Patent and Trademark Office.

Wang, X., & Sun, H. H. (1994). U.S. Patent No. 5,309,917. Washington, DC: U.S. Patent and Trademark Office.

Dayra, Como redactar y publicar artículos científicos. Organización Panamericana de Salud, 1994.

Zhang H., Lihwa L. (2013). The effectiveness of an education program on nurses’ knowledge of electrocardiogram interpretation. International Emergency Nursing, 22, pp. 247-251.

Muller M., Christ T., Dobrev D., Nitsche I., Stehr S., Ravens U., Koch T., 2005 Teaching antiarrhythmic therapy and ECG in simulator-based interdisciplinary undergraduate medical education. British Journal of Anaesthesia, 95, pp. 300-304.

McClauley B., Chu A. (2017). Using mobile device technology and spaced education adaptive learning algorithms to teach ECG interpretation. Journal of the American College of Cardiology, 69, p. 2492.

Baral R., Declan C., Mahmood A., Vassilios S. (2020). The effectiveness of a nationwide interactive ECG teaching workshop for UK medical students. Journal of Electrocardiology, 58, pp. 74-79.

Breen c., Kelly G., Kernohan W,. (2019). ECG interpretation skill acquisition: A review of learning, teaching and assessment. Journal of Electrocardiology, 39, pp. 30-35.

Liu J., Zhang C., Ristaniem T., Parviainen T., Cong F. (2020). Automated detection and localization system of myocardial infarction in single-beat ECG using Dual-Q TQWT and wavelet packet tensor decomposition. Coputer Methods and Programs in Biomedicine, 184, pp. 105-120.

Appathuari A., Jerusalin C., Kumar S., Ashy V., Ganana a., Lenin a., Krishnamoorthy S. (2019). A study on ECG signal characterization and practical implementation of some ECG characterization techniques. Measurement, 147, p. 384.

Sidkova M., Ladrova M., Martinek R., Kahanek M., Bilik P., Jaros R. (2019). Adaptive fetal ECG signal extraction based on LabVIEW and C# implementation. IFAC- PapersOnLine, 52, pp. 359-364.

Novotny T, Bond R., Andrsova., Koc L., Sisakova M., Finaly D., Guldering D., Spinar J., Malik M. (2015). Data analysis of diagnostic accuracies in 12-lead electrocardiogram interpretation by junior medical fellows. Journal of Electrocardiology, 48, pp. 988-994.

Anas M., Norali A., Jun W. (2014). On-line Monitoring and Analysis of Bioelectrical Signals. Procedia computer Science, 42, pp.365-371.