Staged Parameter Identification Method for Non-Homogeneous Fractional-Order Hammerstein MISO Systems Using Multi-Innovation LM: Application to Heat Flow Density Modeling

Staged Parameter Identification Method for Non-Homogeneous Fractional-Order Hammerstein MISO Systems Using Multi-Innovation LM: Application to Heat Flow Density Modeling

For the non-homogeneous fractional-order Hammerstein multiple input single output (MISO) system, a method for identifying system coefficients and fractional-order parameters in stages is proposed. The coefficients of the system include the coefficients of nonlinear terms and the coefficients of the...

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Bibliographic Details
Main Authors: Chunlei Liu, Hongwei Wang, Yi An
Format: Article
Language:English
Published: MDPI AG 2025-02-01
Series:Fractal and Fractional
Subjects:
parameter identification
MISO system
non-homogeneous fractional order
three stages
multi-innovation LM
Online Access:https://www.mdpi.com/2504-3110/9/3/150
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Summary:For the non-homogeneous fractional-order Hammerstein multiple input single output (MISO) system, a method for identifying system coefficients and fractional-order parameters in stages is proposed. The coefficients of the system include the coefficients of nonlinear terms and the coefficients of the transfer function. In order to estimate them, we derived the coupling auxiliary form between the original system coefficients, developed a multi-innovation principle combined with the LM (Levenberg–Marquardt) parameter identification method, and introduced a decoupling strategy for the coupling coefficients. The entire identification process of fractional orders is split into three stages. The division of stages is based on assuming that the system is of different fractional order types, including global homogeneous fractional-order systems, local homogeneous fractional-order systems, and non-homogeneous fractional-order systems. Except for the first stage, the estimated initial value of the fractional order in each stage is derived from the estimated value of the fractional order in the previous stage. The fractional order iteration will re-drive the iteration of the system coefficients to achieve the purpose of alternate estimation. To validate the proposed algorithm, we modeled the fractional-order system of heat flow density through a two-layer wall system, demonstrating the algorithm’s effectiveness and practical applicability.
ISSN:2504-3110

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