On the Relation Between Discrete and Continuous-Time Refined Instrumental Variable Methods

被引：1

作者：

Gonzalez, Rodrigo A. ^{[1
]}

Rojas, Cristian R. ^{[2
]}

Pan, Siqi ^{[3
]}

Welsh, James S. ^{[3
]}

机构：

[1] Eindhoven Univ Technol, Control Syst Technol Res Sect, NL-5612 AZ Eindhoven, Netherlands

[2] KTH Royal Inst Technol, Div Decis & Control Syst, S-10044 Stockholm, Sweden

[3] Univ Newcastle, Sch Engn, Callaghan, NSW 2308, Australia

来源：

IEEE CONTROL SYSTEMS LETTERS | 2023年 / 7卷

基金：

瑞典研究理事会;

关键词：

Instruments; System identification; Computed tomography; Transfer functions; Optimization; Linear systems; Mathematical models; Identification; refined instrumental variables; parsimony;

D O I：

10.1109/LCSYS.2023.3282445

中图分类号：

TP [自动化技术、计算机技术];

学科分类号：

0812 ;

摘要：

The Refined Instrumental Variable method for discrete-time systems (RIV) and its variant for continuous-time systems (RIVC) are popular methods for the identification of linear systems in open-loop. The continuous-time equivalent of the transfer function estimate given by the RIV method is commonly used as an initialization point for the RIVC estimator. In this letter, we prove that these estimators share the same converging points for finite sample size when the continuous-time model has relative degree zero or one. This relation does not hold for higher relative degrees. Then, we propose a modification of the RIV method whose continuous-time equivalent is equal to the RIVC estimator for any non-negative relative degree. The implications of the theoretical results are illustrated via a simulation example.

引用

页码：2233 / 2238

页数：6

共 50 条

[31] INSTRUMENTAL VARIABLES AND LSM IN CONTINUOUS-TIME PARAMETER ESTIMATION
Escobar, Jesica
Enqvist, Martin
[J]. ESAIM-CONTROL OPTIMISATION AND CALCULUS OF VARIATIONS, 2017, 23 (02) : 427 - 442
[32] Continuous-time QBD processes with continuous phase variable
Li, Quan-Lin
Lin, Chuang
[J]. COMPUTERS & MATHEMATICS WITH APPLICATIONS, 2006, 52 (10-11) : 1483 - 1510
[33] Continuous-time consensus with discrete-time communications
Almeida, Joao
Silvestre, Carlos
Pascoal, Antonio M.
[J]. SYSTEMS & CONTROL LETTERS, 2012, 61 (07) : 788 - 796
[34] DISCRETE-TIME DEMODULATION OF CONTINUOUS-TIME SIGNALS
KELLY, CN
GUPTA, SC
[J]. IEEE TRANSACTIONS ON INFORMATION THEORY, 1972, 18 (04) : 488 - +
[35] An approach to bridging the gap between discrete-time and continuous-time coupled systems
Pham Anh Chuong Tran
Tsubone, Tadashi
[J]. 2019 IEEE INTERNATIONAL SYMPOSIUM ON CIRCUITS AND SYSTEMS (ISCAS), 2019,
[36] Comparison between continuous-time asynchronous and discrete-time synchronous iterative decoding
Hemati, S
Banihashemi, AH
[J]. GLOBECOM '04: IEEE GLOBAL TELECOMMUNICATIONS CONFERENCE, VOLS 1-6, 2004, : 356 - 360
[37] REFINED INSTRUMENTAL VARIABLE METHODS OF RECURSIVE TIME-SERIES ANALYSIS .2. MULTIVARIABLE SYSTEMS
JAKEMAN, A
YOUNG, P
[J]. INTERNATIONAL JOURNAL OF CONTROL, 1979, 29 (04) : 621 - 644
[38] Continuous-Time Distributed Observers With Discrete Communication
Doerfler, Florian
Pasqualetti, Fabio
Bullo, Francesco
[J]. IEEE JOURNAL OF SELECTED TOPICS IN SIGNAL PROCESSING, 2013, 7 (02) : 296 - 304
[39] FEEDBACK MODELS FOR DISCRETE AND CONTINUOUS-TIME SERIES
ZEGER, SL
LIANG, KY
[J]. STATISTICA SINICA, 1991, 1 (01) : 51 - 64
[40] Control of continuous-time systems with discrete jumps
Shi, P
[J]. JOURNAL OF THE AUSTRALIAN MATHEMATICAL SOCIETY SERIES B-APPLIED MATHEMATICS, 1999, 41 : 58 - 82

← 1 2 3 4 5 →