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Proportional-Derivative (PD) control is a widely used control method in various engineering systems to enhance stability and performance. In a system with only proportional control, common issues include high maximum overshoot and oscillation, observed in both the error signal and its rate of change. This behavior can be divided into three distinct phases: initial overshoot, subsequent undershoot, and gradual stabilization.
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The Discrete Fourier Transform (DFT) is a fundamental tool in signal processing, extending the discrete-time Fourier transform by evaluating discrete signals at uniformly spaced frequency intervals. This transformation converts a finite sequence of time-domain samples into frequency components, each representing complex sinusoids ordered by frequency. The DFT translates these sequences into the frequency domain, effectively indicating the magnitude and phase of each frequency component present...
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Related Experiment Video

Updated: Jun 14, 2025

Design and Application of a Fault Detection Method Based on Adaptive Filters and Rotational Speed Estimation for an Electro-Hydrostatic Actuator
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Robust post-processing time frequency technology and its application to mechanical fault diagnosis.

Junbo Long1, Changshou Deng2, Haibin Wang3

  • 1College of Electronic Information Engineering, Jiujiang University, Jiujiang, China.

Scientific Reports
|September 3, 2024
PubMed
Summary
This summary is machine-generated.

New fault diagnosis methods improve time-frequency resolution for signals with infinite variance processes. These robust techniques outperform traditional methods in complex noise environments, enhancing diagnostic accuracy for machinery like bearings.

Keywords:
Feature extractionFuzzy energyInfinite variance processMulti-synchrosqueezingSynchrosqueezing extracting

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Area of Science:

  • Signal Processing
  • Mechanical Engineering
  • Fault Diagnosis

Background:

  • Traditional synchrosqueezing transform (SST) and synchroextracting transform (SET) methods enhance time-frequency resolution (TFR) for fault diagnosis.
  • Normal and fault signals, including background noise, can be modeled as infinite variance processes (1 < α ≤ 2), challenging conventional TFR methods.
  • The efficacy of standard SST and SET is significantly diminished in infinite variance process environments.

Purpose of the Study:

  • To develop robust post-processing methods for improving TFR resolution in fault diagnosis under infinite variance process conditions.
  • To mathematically derive and validate novel algorithms designed to overcome the limitations of traditional methods in complex signal environments.

Main Methods:

  • Proposed robust post-processing techniques: FSET, FSSET, FSOSET, and FMSST.
  • Utilized infinite variance process statistical models and the FLOS technique for algorithm development.
  • Completed mathematical derivations for the proposed methods.

Main Results:

  • The proposed methods demonstrate superior performance compared to conventional SST and SET techniques.
  • Applied to diagnose bearing outer race signals corrupted by infinite variance processes, the new methods show significant performance advantages.
  • Comparative analysis confirms the enhanced TFR resolution and diagnostic accuracy of the novel algorithms.

Conclusions:

  • The developed FSET, FSSET, FSOSET, and FMSST methods offer robust solutions for fault diagnosis in signals characterized by infinite variance processes.
  • These advanced algorithms provide improved TFR resolution and diagnostic performance, particularly in noisy and complex signal conditions.
  • The study summarizes the characteristics, limitations, and application scenarios of the improved algorithms for future research and industrial implementation.