SISTEMA DE VALIDACIÓN DE AMPLIFICADORES OPERACIONALES Y DE INSTRUMENTACIÓN UTILIZANDO LabVIEW (OPERATIONAL AND INSTRUMENTATION AMPLIFIERS VALIDATION SYSTEM USING LabVIEW)

Francisco Javier Enríquez Aguilera, José David Díaz Román, Abel Eduardo Quezada Carreón, Juan de Dios Cota Ruiz, Ana Luz Portillo Hernández

Resumen


Resumen
En este trabajó se realizó un sistema para validar el funcionamiento de amplificadores operacionales TLC274, LM358 y TL084 y el amplificador de instrumentación AD620. Se describe el diseño y fabricación de la tarjeta de circuito impreso, así como la etapa para acoplar los componentes necesarios y el desarrollo del software para la interfaz de usuario de manera que facilite su uso. Se desarrolló un programa en LabVIEW que permite verificar el funcionamiento de los dispositivos mencionados de manera semiautomatizada. El sistema ha demostrado ser de gran ayuda para llevar a cabo un mejor control e inventario de estos recursos del laboratorio, permitiendo detectar rápidamente fallas en los componentes puestos a prueba. Asimismo, ha conducido a que en las prácticas de laboratorio los alumnos obtengan los resultados esperados en menor tiempo y que las actividades prácticas se lleven a cabo con mayor seguridad.
Palabras Clave: Amplificadores operacionales, LabVIEW, Instrumentación.

Abstract
In this paper, a system was developed to validate the operation of TLC274, LM358, and TL084 operational amplifiers, and the AD620 instrumentation amplifier. The design and manufacture of the printed circuit board are described, as well as the stage to couple the necessary components and the development of the software for the user interface in a way that facilitates its use. A program was developed in LabVIEW that allows verifying the operation of the aforementioned devices in a semi-automated way. The system has proven to be of great help to carry out a better control and inventory of these laboratory resources, allowing to quickly detection failures in the components under test. Likewise, it has allowed students to obtain the expected results in less time in laboratory sessions and those practical activities are carried out with greater certitude.
Keywords: Operational amplifier, LabVIEW, Instrumentation.

Texto completo:

250-266 PDF

Referencias


Buangam, W., & Meesrisuk, W. (2018). Implementation of Real-Time Power Swing Detection Based on Support Vector Machine of Distributed Generation System Using LabVIEW MyRIO. ICEMS 2018 - 2018 21st International Conference on Electrical Machines and Systems, 2, 1088–1093. https://doi.org/10.23919/ICEMS.2018.8549072

Chew, M. T., Demidenko, S., Ooi, M. P. L., & Kuang, Y. C. (2017, June). Family of low-cost NI ELVIS/LabVIEW-based semiconductor testers for engineering education. In 2017 IEEE International Conference on Computational Intelligence and Virtual Environments for Measurement Systems and Applications, CIVEMSA 2017-Proceedings (pp. 165-170).

Eichhorn, S., Reisinger, T., Böhm, J., Voss, S., Doppler, S., Lange, R., & Krane, M. (2019). Development and validation of a measurement system for continuously monitoring postoperative reservoir levels. Australasian Physical and Engineering Sciences in Medicine, 42(2), 611–617. https://doi.org/10.1007/s13246-019-00746-5

Gergič, B., & Hercog, D. (2019). Design and implementation of a measurement system for high-speed testing of electromechanical relays. Measurement, 135, 112-121.

Georgiana, H. C., Ana-Maria, B., & Ioan, L. (2018). Automatic testing of automotive electronic modules for cranking conditions. 2018 13th International Symposium on Electronics and Telecommunications, ISETC 2018 - Conference Proceedings, 1–4. https://doi.org/10.1109/ISETC.2018.8583856

Ishafit, I., Indratno, T. K., & Prabowo, Y. D. (2019). Arduino and LabVIEW-based remote data acquisition system for magnetic field of coils experiments. Physics Education, 55(2), 025003.

Lai, A., Serpi, A., Sulis, S., & Gatto, G. (2019). Extensive sensitivity analysis of Implantable Cardioverter Defibrillators by an Automatic Sensing Test procedure. Measurement: Journal of the International Measurement Confederation, 134, 930–938. https://doi.org/10.1016/j.measurement.2018.12.048

Perişoară, L. A., Vasile, A., & Săcăleanu, D. L. (2017, October). Vehicles diagnosis based on LabVIEW and CAN interfaces. In 2017 IEEE 23rd International Symposium for Design and Technology in Electronic Packaging (SIITME) (pp. 383-386). IEEE.

Syafa, L. (Electrical E. D., Malang), U. of M., Fauziyah, L. (Electrical E. D., ) U. of M. M., Has, Z. (Electrical E. D., & ) U. of M. M. (2018). Robust and Accurate Positioning Control of Solar. 324–329.






URL de la licencia: https://creativecommons.org/licenses/by/3.0/deed.es

Barra de separación

Licencia Creative Commons    Pistas Educativas está bajo la Licencia Creative Commons Atribución 3.0 No portada.    

TECNOLÓGICO NACIONAL DE MÉXICO / INSTITUTO TECNOLÓGICO DE CELAYA

Antonio García Cubas Pte #600 esq. Av. Tecnológico, Celaya, Gto. México

Tel. 461 61 17575 Ext 5450 y 5146

pistaseducativas@itcelaya.edu.mx

http://itcelaya.edu.mx/ojs/index.php/pistas