Showing total 4 results

1. Exploiting Sparsity in Tight-Dimensional Spaces for Piecewise Continuous Signal Recovery.

Author

Kuroda, Hiroki, Yamagishi, Masao, and Yamada, Isao

Subjects

*SIGNAL processing, *POLYNOMIALS, *SUBSPACES (Mathematics), *DISCRETE systems, *NOISE measurement

Abstract

Recovery of certain piecewise continuous signals from noisy observations has been a major challenge in sciences and engineering. In this paper, in a tight-dimensional representation space, we exploit sparsity hidden in a class of possibly discontinuous signals named finite-dimensional piecewise continuous (FPC) signals. More precisely, we propose a tight-dimensional linear transformation which reveals a certain sparsity in discrete samples of the FPC signals. This transformation is designed by exploiting the fact that most of the consecutive samples are contained in special subspaces. Numerical experiments on recovery of piecewise polynomial signals and piecewise sinusoidal signals show the effectiveness of the revealed sparsity. [ABSTRACT FROM AUTHOR]

Published

2018

2. Performance Tradeoffs for Networked Jump Observer-Based Fault Diagnosis.

Author

Dolz, Daniel, Penarrocha, Ignacio, and Sanchis, Roberto

Subjects

*DEBUGGING, *FALSE alarms, *MARKOV processes, *SIGNAL processing, *GAUSSIAN processes

Abstract

In this paper, we address the fault diagnosis problem for discrete-time multi-sensor systems over communication networks with measurement dropouts. We use the measurement outcomes to model the measurement reception scenarios. Based on this, we propose the use of a jump observer to diagnose multiple faults. We model the faults as slow time-varying signals and introduce this dynamic in the observer to estimate the faults and to generate a residual. The fault detection is assured by comparing the residual signal with a prescribed threshold. We design the jump observer, the residual and the threshold to attain disturbance attenuation, fault tracking and detection conditions and a given false alarm rate. The false alarm rate is upper bounded by means of Markov’s inequality. We explore the tradeoffs between the minimum detectable faults, the false alarm rate and the response time to faults of the fault diagnoser. By imposing the disturbances and measurement noises to be Gaussian, we tighten the false alarm rate bound which improves the time needed to detect a fault. A numerical example is provided to illustrate the effectiveness of the theory developed in the paper. [ABSTRACT FROM PUBLISHER]

Published

2015

3. A Noise Resistant Correlation Method for Period Detection of Noisy Signals.

Author

Fan, Wei, Li, Yongxiang, Tsui, Kwok Leung, and Zhou, Qiang

Subjects

*SIGNAL detection, *SIGNAL processing, *SIGNAL denoising, *RANDOM noise theory, *FAULT diagnosis

Abstract

This paper develops a novel method called the noise resistant correlation method for detecting the hidden period from the contaminated (noisy) signals with strong white Gaussian noise. A novel correlation function is proposed based on a newly constructed periodic signal and the contaminated signal to effectively detect the target hidden period. In contrast with the conventional autocorrelation analysis (AUTOC) method, this method demonstrates excellent performance, especially when facing strong noise. Fault diagnoses of rolling element bearings and gears are presented as application examples and the performance of the proposed method is compared with that of the AUTOC method. [ABSTRACT FROM AUTHOR]

Published

2018

4. Robust Fault Isolation With Statistical Uncertainty in Identified Parameters.

Author

Jianfei Dong, Verhaegen, M., and Gustafsson, F.

Subjects

*SIGNAL processing, *SIGNAL theory, *PARAMETERS (Statistics), *INFORMATION theory, *ACTUATORS, *DETECTORS

Abstract

This correspondence is a companion paper to [J. Dong, M. Verhaegen, and F. Gustafsson, “Robust Fault Detection With Statistical Uncertainty in Identified Parameters,” IEEE Trans. Signal Process., vol. 60, no. 10, Oct. 2012], extending it to fault isolation. Also, here, use is made of a linear in the parameters model representation of the input-output behavior of the nominal system (i.e. fault-free). The projection of the residual onto directions only sensitive to individual faults is robustified against the stochastic errors of the estimated model parameters. The correspondence considers additive error sequences to the input and output quantities that represent failures like drift, biased, stuck, or saturated sensors/actuators. [ABSTRACT FROM PUBLISHER]

Published

2012