Knock Detection in Spark Ignition Engines Base on Complementary Ensemble Empirical Mode Decomposition-Hilbert Transform

Bi, Fengrong; Ma, Teng; Zhang, Jian; Li, Lin; Shi, Chun-Fang

doi:10.1155/2016/9507540

Cited by 8 publications

(9 citation statements)

References 16 publications

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“…The Rossby normal modes are calculated by Equation 5. Since Equation 5 consists of trigonometric functions, Figure 7a is featured by undulating wave train, and it has 5/5, 10/12, 16/18 similarities with field K. The amplitude of field F is different from field K, because the amplitude of signals cannot be well preserved by the band-pass filter, and the ensemble method in EMD algorithm (e.g., CEEMD) can present the characteristics of the original signal accurately (Bi et al, 2016). However, in the perspective of the positive-negative spatial pattern, similarity between field F and field K is very high.…”

Section: Spatial Patternsmentioning

confidence: 99%

The Rossby Normal Mode as a Physical Linkage in a Machine Learning Forecast Model for the SST and SSH of South China Sea Deep Basin

Lin,

Zhang,

Zhang

et al. 2023

JGR Oceans

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Machine learning (ML) has been widely applied in Earth sciences, but its black‐box nature still remains. Existing techniques for interpretable ML developed by deep learning researchers are not satisfactory in understanding physical problems. In this study, our objective is to establish the physical linkage between features extracted from ML model and results derived from physical equations that describe the problem. This approach aims to provide a more comprehensible way of understanding an ML model. We select a less complex ML forecasting model, consisting of traditional statistical algorithms, which effectively forecast sea surface temperature anomaly (SSTA) and sea level anomaly (SLA) of the South China Sea (SCS) in 30 days ahead. Here, we focus on the SLA prediction and detect the physical mechanism of model capability to predict SCS SLA. Previous study has identified Rossby normal modes as the physical mechanism for long‐lived eddies in SCS in previous study. We here demonstrate the relationship between the ML model and Rossby normal modes in SCS in terms of temporal variations and spatial distributions of water mass. The model's skill in predicting Rossby normal modes partially explains its skill in predicting SLA, thereby providing a more transparent and interpretable basis for forecasts in SCS.

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Section: Spatial Patternsmentioning

confidence: 99%

The Rossby Normal Mode as a Physical Linkage in a Machine Learning Forecast Model for the SST and SSH of South China Sea Deep Basin

Lin,

Zhang,

Zhang

et al. 2023

JGR Oceans

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“…In-cylinder pressure and the corresponding engine block vibration signals are taken from the research by Fengrong et al [31][32][33]. They had captured the signals from 4 cylinders, 4-stroke, in-line SI engine.…”

Section: Engine Block Vibration Analysis and System Controlmentioning

confidence: 99%

“…In this work, the in-cylinder pressure and denoised vibration signals are analyzed to extract the features of knock. The signals are decomposed using EMD, even though there are many improved models like EEMD [9,20], Complementary Ensemble Empirical Mode Decom-position [31], etc. This is due to the better adaptability of EMD in decomposing the signals, i.e., it could naturally deal with the non-stationarities and nonlinearities.…”

Section: Introductionmentioning

confidence: 99%

Engine block vibrations: An indicator of knocking in the SI engine

Joseph,

Thampi

2023

FME Transactions

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The factors influencing the onset of knocking have a significant impact on how well a SI engine performs. Hence, the efficacy in determining the onset and controlling of knock is a key factor in improving the SI engine's performance. This paper provides insight into the role of engine block vibrations in determining the occurrence of knock using Empirical Mode Decomposition and Short-Time Fourier Transform. To comprehend the behaviour of vibration amid normal combustion and knocking conditions, the engine block vibration signals are analyzed and compared with the incylinder pressure fluctuations. The features of knock are extracted from the engine block vibration signals using Empirical Mode Decomposition. The first Intrinsic Mode Function (IMF) thus obtained is used to generate the Hilbert spectrum for detecting the occurrence of knock. Similarly, ShortTime Fourier Transform is also performed on the first IMF to obtain the spectrogram. The findings demonstrate unequivocally that higher frequency variations are produced when knock occurs. These results also indicate that the combination of Empirical Mode Decomposition and Short-Time Fourier Transform can be used effectively for determining the occurrence of knock.

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“…Empirical mode decomposition (EMD) [31] is self-adaptable and decomposes a signal directly into several IMFs, which are defined as amplitudemodulated-frequency-modulated signals whose number of local extrema and zerocrossings differ at most by one [13]. For the phenomenon that mode mixing occurs repeatedly in EMD, ensemble empirical mode decompositionEMD (EEMD), which is proposed that decreases the chance of undue mode mixing to a certain extent, was proposed [5]. The IMF in EEMD is characterized as the mean of an ensemble of trials whereby a finite-amplitude white noise signal is added to the decomposed data in each trial;, with this approach increases the increase of computational burden since the data size of IMF is equal to that of the raw data.…”

Section: Completed Files By Springer Nature Author Servicesmentioning

confidence: 99%

A Novel Multiple Feature-Based Engine Knock Detection System using Sparse Bayesian Extreme Learning Machine

et al. 2022

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Dear Zhaoxu Yang, Thank you for choosing Springer Nature Author Services. This manuscript, titled "A Novel Multiple Feature-based Engine Knock Detection System using a Sparse Bayesian Extreme Learning Machine," is very interesting. The paper was edited for grammar, phrasing, and punctuation. In addition, many edits were made to further improve the flow and readability of the text. Below, we highlight the areas of this paper that we focused on in our edit.Articles are an important aspect of the English language, including the definite article "the" and the indefinite articles "a" and "an." Our edits focused on improving article use, which is often strongly dependent on context and field conventions.The easiest way to avoid using vague pronouns in your writing is to use demonstrative pronouns as adjectives that modify a more descriptive term (e.g., "This inconsistency" or "These findings") and to replace pronouns such as "It" with more specific nouns.Certain edits were made to remove redundant, repetitive or unnecessary phrasing and to present the information in a more straightforward manner.Comments were left if further clarification would be helpful or confirmation of the meaning of the text was necessary. Please review these comments and all our changes carefully for more detailed suggestions, as well as to ensure that the final version of the manuscript is fully accurate.Thank you again for using our editing services; we wish you the best of luck with your submission.

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Knock Detection in Spark Ignition Engines Base on Complementary Ensemble Empirical Mode Decomposition-Hilbert Transform

Cited by 8 publications

References 16 publications

The Rossby Normal Mode as a Physical Linkage in a Machine Learning Forecast Model for the SST and SSH of South China Sea Deep Basin

The Rossby Normal Mode as a Physical Linkage in a Machine Learning Forecast Model for the SST and SSH of South China Sea Deep Basin

Engine block vibrations: An indicator of knocking in the SI engine

A Novel Multiple Feature-Based Engine Knock Detection System using Sparse Bayesian Extreme Learning Machine

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