Diseño y caracterización de un tubo de impedancias con sensores acústicos de bajo costo

Autores/as

  • Jaime Ricardo González-Romero Universidad de Guadalajara
    jaimer.gonzalezr@academicos.udg.mx
  • Adalberto Zamudio-Ojeda Universidad de Guadalajara
  • Guillermo Garcia-Torales Universidad de Guadalajara

DOI:

https://doi.org/10.66482/ekwpfp65

Palabras clave:

acústica, tubo de impedancias, sensores acústicos, calibración.

Resumen

En este trabajo se presenta el diseño, construcción y caracterización de un tubo de impedancias acústicas accesible, adecuado para análisis en el rango de 20 Hz a 4 kHz. El dispositivo fue fabricado con materiales comerciales y emplea una configuración de dos sensores acústicos económicos. Se describe el desarrollo de un algoritmo para la calibración de los sensores, basado en la norma ASTM E1050-12, reemplazando el analizador de espectro por un osciloscopio digital. Las señales adquiridas en el dominio del tiempo se transforman al dominio de la frecuencia para obtener su espectro y aplicar el procedimiento de calibración. Aunque el sistema aún está en fase de validación, los resultados preliminares indican un comportamiento coherente con lo esperado teóricamente. Este desarrollo busca fomentar el uso de herramientas accesibles para la caracterización acústica de materiales en contextos educativos o de investigación aplicada.

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Biografía del autor/a

  • Jaime Ricardo González-Romero, Universidad de Guadalajara

    He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.He received his Ph.D. degree in electronic and computation from the University of Guadalajara, Mexico, in 2022. He is currently an associate professor of University of Guadalajara, Mexico, since 2015. His area of interest is laser technology, optical metrology, photonics, and wave propagation. He is also interested in material science, laser shock processing, electronic measurement systems for optical applications, and optomechanical design. Currently, he studies laser-matter interactions by optical and mechanical techniques, fast phenomena, laser shock waves phenomena, shock waves mitigation, and FEM analysis.

Referencias

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Publicado

2025-08-09

Número

Vol. 1 Núm. 1 (2025): Primera Edición

Sección

Artículo Científico

Licencia

Derechos de autor 2025 Revista Ciencia Aplicada

Creative Commons License

Esta obra está bajo una licencia internacional Creative Commons Atribución-NoComercial-SinDerivadas 4.0.

Cómo citar

González-Romero, J. R., Zamudio-Ojeda, A., & García-Torales, G. (2025). Diseño y caracterización de un tubo de impedancias con sensores acústicos de bajo costo. Revista Ciencia Aplicada, 1(1), 57-69. https://doi.org/10.66482/ekwpfp65