A General Identification Procedure for Reduced-Order Fractional Models Based on the Process Reaction Curve

Juan J. Gude; Antonio Di Teodoro; Oscar Camacho; Pablo García Bringas

doi:10.1016/j.ifacol.2026.01.015

A General Identification Procedure for Reduced-Order Fractional Models Based on the Process Reaction Curve

Juan J. Gude^*
, Antonio Di Teodoro^*
, Oscar Camacho
, Pablo García Bringas^*

^*Autor correspondiente de este trabajo

Ingeniería Electrónica y Automatización

Universidad de Deusto

Producción científica: Contribución a una revista › Artículo de la conferencia › revisión exhaustiva

Resumen

Recent advances in fractional calculus and computation have enabled the development of more accurate and flexible models for industrial process dynamics. Among these, the Fractional First-Order Plus Dead-Time (FFOPDT) and Fractional Dual-Pole Plus Dead-Time (FDPPDT) models have shown notable performance in representing systems with overdamped step responses. This work introduces a unified analytical identification procedure for both models, derived from the process reaction curve obtained through a simple open-loop step test. The proposed methodology is validated through numerical simulations, and the results demonstrate that it achieves comparable or superior performance to existing methods, with the added benefits of analytical simplicity and computational efficiency, making it suitable for industrial applications.

Idioma original	Inglés
Páginas (desde-hasta)	85-90
Número de páginas	6
Publicación	IFAC-PapersOnLine
Volumen	59
N.º	37
DOI	https://doi.org/10.1016/j.ifacol.2026.01.015
Estado	Publicada - 1 dic. 2025
Evento	13th IFAC Conference on Fractional Differentiation and its Applications, ICFDA 2025 - Algiers, Argelia Duración: 16 dic. 2025 → 18 dic. 2025

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title = "A General Identification Procedure for Reduced-Order Fractional Models Based on the Process Reaction Curve",

abstract = "Recent advances in fractional calculus and computation have enabled the development of more accurate and flexible models for industrial process dynamics. Among these, the Fractional First-Order Plus Dead-Time (FFOPDT) and Fractional Dual-Pole Plus Dead-Time (FDPPDT) models have shown notable performance in representing systems with overdamped step responses. This work introduces a unified analytical identification procedure for both models, derived from the process reaction curve obtained through a simple open-loop step test. The proposed methodology is validated through numerical simulations, and the results demonstrate that it achieves comparable or superior performance to existing methods, with the added benefits of analytical simplicity and computational efficiency, making it suitable for industrial applications.",

keywords = "FDPPDT, FFOPDT, Fractional systems, Process Identification, Reaction Curve",

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AU - Gude, Juan J.

AU - Di Teodoro, Antonio

AU - Camacho, Oscar

AU - Bringas, Pablo García

PY - 2025/12/1

Y1 - 2025/12/1

N2 - Recent advances in fractional calculus and computation have enabled the development of more accurate and flexible models for industrial process dynamics. Among these, the Fractional First-Order Plus Dead-Time (FFOPDT) and Fractional Dual-Pole Plus Dead-Time (FDPPDT) models have shown notable performance in representing systems with overdamped step responses. This work introduces a unified analytical identification procedure for both models, derived from the process reaction curve obtained through a simple open-loop step test. The proposed methodology is validated through numerical simulations, and the results demonstrate that it achieves comparable or superior performance to existing methods, with the added benefits of analytical simplicity and computational efficiency, making it suitable for industrial applications.

AB - Recent advances in fractional calculus and computation have enabled the development of more accurate and flexible models for industrial process dynamics. Among these, the Fractional First-Order Plus Dead-Time (FFOPDT) and Fractional Dual-Pole Plus Dead-Time (FDPPDT) models have shown notable performance in representing systems with overdamped step responses. This work introduces a unified analytical identification procedure for both models, derived from the process reaction curve obtained through a simple open-loop step test. The proposed methodology is validated through numerical simulations, and the results demonstrate that it achieves comparable or superior performance to existing methods, with the added benefits of analytical simplicity and computational efficiency, making it suitable for industrial applications.

KW - FDPPDT

KW - FFOPDT

KW - Fractional systems

KW - Process Identification

KW - Reaction Curve

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DO - 10.1016/j.ifacol.2026.01.015

M3 - Artículo de la conferencia

AN - SCOPUS:105029897414

SN - 2405-8971

VL - 59

SP - 85

EP - 90

JO - IFAC-PapersOnLine

JF - IFAC-PapersOnLine

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T2 - 13th IFAC Conference on Fractional Differentiation and its Applications, ICFDA 2025

Y2 - 16 December 2025 through 18 December 2025

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A General Identification Procedure for Reduced-Order Fractional Models Based on the Process Reaction Curve

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