Ajuste fino de un modelo de producción vocal para estimar el estrés de impacto utilizando un método metaheurístico

Fine-Tuning of a Voice Production Model to Estimate Impact Stress Using a Metaheuristic Method

Publicado 2024-01-29 — Actualizado el 2024-02-03

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Vol. 6 Núm. 1 (2024)
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Artículos de investigación
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Ajuste fino de un modelo de producción vocal para estimar el estrés de impacto utilizando un método metaheurístico. Rev. Investig. Innov. Cienc. Salud [Internet]. 2024 Feb. 3 [cited 2024 Dec. 21];6(1):24-43. Available from: https://riics.info/index.php/RCMC/article/view/234
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https://doi.org/10.46634/riics.234
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Esta obra está bajo una licencia internacional Creative Commons Atribución-NoComercial-SinDerivadas 4.0.

Carlos-Alberto Calvache-Mora
Department of Mechatronics Engineering; Universidad Militar Nueva Granada; Bogotá, Colombia. / Vocology Research; Vocology Center; Bogotá; Colombia. / Communication Science and Disorders; Corporación Universitaria Iberoamericana; Bogotá; Colombia.
    https://orcid.org/0000-0002-5403-1852
    Leonardo Soláque
    Department of Mechatronics Engineering; Universidad Militar Nueva Granada; Bogotá, Colombia
      https://orcid.org/0000-0002-2773-1028
      Alexandra Velasco
      Department of Mechatronics Engineering; Universidad Militar Nueva Granada; Bogotá, Colombia
        https://orcid.org/0000-0001-7786-880X
        Lina Peñuela
        Department of Mechatronics Engineering; Universidad Militar Nueva Granada; Bogotá, Colombia
          https://orcid.org/0000-0002-1925-9296
          Mostrar biografía de los autores

          Introducción. En modelos de producción vocal que emplean estructuras de resorte-masa-amortiguador, la precisión en la determinación de coeficientes de amortiguamiento que se asemejen a las características fisiológicas de las cuerdas vocales es crucial, teniendo en cuenta posibles variaciones en la representación de la viscoelasticidad.

          Objetivo. Este estudio tiene como objetivo realizar un ajuste paramétrico de un modelo de producción vocal basado en un sistema de resorte-masa-amortiguador que incorpora interacción con la presión subglótica, con el fin de modelar de manera precisa las fuerzas de colisión ejercidas por las cuerdas vocales durante la fonación.

          Método. Se utilizó un algoritmo de búsqueda metaheurística para la síntesis paramétrica. El algoritmo se aplicó a los coeficientes de elasticidad c1 y c2, así como a los coeficientes de amortiguamiento ε1 y ε2, que se correlacionan directamente con las matrices de masa del modelo. Esto facilita el ajuste de la composición de las cuerdas para lograr un comportamiento fisiológico deseado.

          Resultados. El comportamiento del sistema vocal para cada ciclo de simulación se comparó con un estándar predefinido en condiciones normales. El algoritmo determinó el punto final de la simulación evaluando las discrepancias entre características clave de las señales obtenidas y las deseadas.

          Conclusión. El ajuste paramétrico permitió la aproximación del comportamiento fisiológico de la producción vocal, proporcionando estimaciones de las fuerzas de impacto experimentadas por las cuerdas vocales durante la fonación.

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