Smoothing the LPM Estimate of the Frequency Response Function Via an Impulse Response Truncation Technique

Mikaya Lumori; Egon Geerardyn; Joannes Schoukens; John Lataire

Smoothing the LPM Estimate of the Frequency Response Function Via an Impulse Response Truncation Technique

Mikaya Lumori, Egon Geerardyn, Joannes Schoukens, John Lataire

Electricity

Research output: Contribution to journal › Article › peer-review

3 Citations (Scopus)

Abstract

A statistical impulse response truncation technique is applied to the local polynomial method (LPM)-estimate of the frequency response function (FRF), resulting in an improved, smooth FRF. Formulated as a nonparametric linear-least-squares-estimate, the LPM is first applied to estimate the FRF from a full data record of a single-input-single-output system, systematically expressed in an output-error framework. The smooth characteristics of both the exact FRF and the leakage from transients allow for an optimal application of the local polynomial method, leading to the elimination of both the leakage and interpolation errors. The truncation method introduced in this paper makes it possible for the user to fine-tune the tradeoff between the uncertainty (variance) and the bias on the estimated instantaneous FRF.

Original language	English
Pages (from-to)	214-220
Number of pages	7
Journal	IEEE Transactions on Instrumentation and Measurement
Volume	63
Publication status	Published - 1 Jan 2014

Keywords

Estimation
frequency domain analysis
frequency response
least squares methods
smoothing methods

Cite this

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title = "Smoothing the LPM Estimate of the Frequency Response Function Via an Impulse Response Truncation Technique",

abstract = "A statistical impulse response truncation technique is applied to the local polynomial method (LPM)-estimate of the frequency response function (FRF), resulting in an improved, smooth FRF. Formulated as a nonparametric linear-least-squares-estimate, the LPM is first applied to estimate the FRF from a full data record of a single-input-single-output system, systematically expressed in an output-error framework. The smooth characteristics of both the exact FRF and the leakage from transients allow for an optimal application of the local polynomial method, leading to the elimination of both the leakage and interpolation errors. The truncation method introduced in this paper makes it possible for the user to fine-tune the tradeoff between the uncertainty (variance) and the bias on the estimated instantaneous FRF.",

keywords = "Estimation, frequency domain analysis, frequency response, least squares methods, smoothing methods",

author = "Mikaya Lumori and Egon Geerardyn and Joannes Schoukens and John Lataire",

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T1 - Smoothing the LPM Estimate of the Frequency Response Function Via an Impulse Response Truncation Technique

AU - Lumori, Mikaya

AU - Geerardyn, Egon

AU - Schoukens, Joannes

AU - Lataire, John

PY - 2014/1/1

Y1 - 2014/1/1

N2 - A statistical impulse response truncation technique is applied to the local polynomial method (LPM)-estimate of the frequency response function (FRF), resulting in an improved, smooth FRF. Formulated as a nonparametric linear-least-squares-estimate, the LPM is first applied to estimate the FRF from a full data record of a single-input-single-output system, systematically expressed in an output-error framework. The smooth characteristics of both the exact FRF and the leakage from transients allow for an optimal application of the local polynomial method, leading to the elimination of both the leakage and interpolation errors. The truncation method introduced in this paper makes it possible for the user to fine-tune the tradeoff between the uncertainty (variance) and the bias on the estimated instantaneous FRF.

AB - A statistical impulse response truncation technique is applied to the local polynomial method (LPM)-estimate of the frequency response function (FRF), resulting in an improved, smooth FRF. Formulated as a nonparametric linear-least-squares-estimate, the LPM is first applied to estimate the FRF from a full data record of a single-input-single-output system, systematically expressed in an output-error framework. The smooth characteristics of both the exact FRF and the leakage from transients allow for an optimal application of the local polynomial method, leading to the elimination of both the leakage and interpolation errors. The truncation method introduced in this paper makes it possible for the user to fine-tune the tradeoff between the uncertainty (variance) and the bias on the estimated instantaneous FRF.

KW - Estimation

KW - frequency domain analysis

KW - frequency response

KW - least squares methods

KW - smoothing methods

M3 - Article

VL - 63

SP - 214

EP - 220

JO - IEEE Transactions on Instrumentation and measurement

JF - IEEE Transactions on Instrumentation and measurement

SN - 0018-9456

ER -

Smoothing the LPM Estimate of the Frequency Response Function Via an Impulse Response Truncation Technique

Abstract

Keywords

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