A Unified Recursive Identification Algorithm with Quantized Observations Based on Weighted Least-Squares Type Criteria

This paper investigates system identification problems with Gaussian inputs and quantized observations under fixed thresholds. By reinterpreting the nonlinear effects induced by quantization as the product of the unknown parameter and an unknown nonlinear coefficient, this work establishes a novel w...

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Bibliographic Details
Published in:IEEE transactions on automatic control pp. 1 - 16
Main Authors: Liu, Xingrui, Wang, Ying, Zhao, Yanlong
Format: Journal Article
Language:English
Published: IEEE 2025
Subjects:
Accuracy
Approximation algorithms
Convergence
convergence analysis
Gaussian inputs
Heuristic algorithms
Linear systems
Noise measurement
Prediction algorithms
quantized observations
Stochastic processes
System identification
Vectors
weighted least-squares
ISSN:0018-9286, 1558-2523
Online Access:Get full text
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Summary:This paper investigates system identification problems with Gaussian inputs and quantized observations under fixed thresholds. By reinterpreting the nonlinear effects induced by quantization as the product of the unknown parameter and an unknown nonlinear coefficient, this work establishes a novel weighted least-squares criterion that enables linear estimation of unknown parameters under quantized observations. Subsequently, a two-step recursive identification algorithm is constructed by estimating two unknown terms, which is capable of handling both Gaussian noisy and noise-free linear systems. Convergence analysis of this identification algorithm is conducted, demonstrating convergence in both almost sure and L p senses under mild conditions, with respective rates of \mathcal{0}(\sqrt{\log \logk / k}) and O(1/k p/2 ), where k denotes the time step. In particular, this algorithm offers an asymptotically efficient estimation of the variance of Gaussian variables using quantized observations. Furthermore, extensions to output-error systems are discussed, enhancing the applicability and relevance of the proposed methods. Two numerical examples are provided to validate these theoretical advancements.
ISSN:0018-9286
1558-2523
DOI:10.1109/TAC.2025.3620623