Una evaluación integral de las técnicas de ia para predecir el índice de calidad del aire: RNN y transformers

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Publicado: Mar 12, 2025
Actualizado: 2025-03-12
Versiones:
2025-03-12 (3)
DOI: https://doi.org/10.17163/ings.n33.2025.06
Palabras clave:
índice de calidad del aire, RNN, LSTM, transformadores, pronóstico de contaminación

Contenido principal del artículo

Pablo Andrés Buestán Andrade
Universidad Católica de Cuenca
https://orcid.org/0000-0002-9210-1591
Pedro Esteban Carrión Zamora
Universidad Católica de Cuenca
https://orcid.org/0009-0007-4230-6891
Anthony Eduardo Chamba Lara
Universidad Católica de Cuenca
https://orcid.org/0009-0003-1231-1068
Juan Pablo Pazmiño Piedra
Universidad Católica de Cuenca
https://orcid.org/0000-0003-0069-7680

Resumen

Este estudio evalúa la eficacia de las redes neuronales recurrentes (RNN) y los modelos basados en transformadores para predecir el índice de calidad del aire (ICA). La investigación compara los modelos RNN tradicionales, incluidos los de memoria a corto y largo plazo (LSTM) y la unidad recurrente controlada (GRU), con arquitecturas avanzadas de transformadores. El estudio utiliza datos de una estación meteorológica en Cuenca, Ecuador, centrándose en contaminantes como CO, NO2, O3, PM2.5 y SO2. Para evaluar el rendimiento de los modelos, se utilizaron métricas clave como el error cuadrático medio (RMSE), el error absoluto medio (MAE) y el coeficiente de determinación (R2). Los resultados del estudio muestran que el modelo LSTM fue el más preciso, alcanzando un R2 de 0,701, un RMSE de 0,087 y un MAE de 0,056. Esto lo convierte en la mejor opción para capturar dependencias temporales en los datos de series temporales complejas. En comparación, los modelos basados en transformadores demostraron tener potencial, pero no lograron la misma precisión que los modelos LSTM, especialmente en datos temporales más complicados. El estudio concluye que el LSTM es más eficaz en la predicción del ICA, equilibrando tanto la precisión como la eficiencia computacional, o que podría ayudar en intervenciones para mitigar la contaminación del aire.

Detalles del artículo

Número
Núm. 33 (2025): enero-junio
Sección
Artículo Científico
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