Artificial intelligence‐assisted fatigue fracture recognition based on morphing and fully convolutional networks

Lyu, Yetao; Yang, Zi; Liang, Hao; Zhang, Beini; Ge, Mingqiao; Li, Rui; Zhang, Zhefeng; Yang, Haokun

doi:10.1111/ffe.13693

Cited by 10 publications

(5 citation statements)

References 32 publications

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“…However, we can draw a conclusion that each of them has its own strength and weakness under different circumstances, which is inevitable. A new method is supposed to be introduced which can combine strengths and avoid weakness [14][15][16].…”

Section: Deductionmentioning

confidence: 99%

Deep learning networks for microbiology images recognition

Chen

2023

Third International Conference on Artificial Intelligence and Computer Engineering (ICAICE 2022)

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As we know, recently deep learning networks have gained currency for some time under the background of the rise of big model, and it has been widely used for various areas including microbiology images recognition. Nowadays deep learning network models are also divided into many different types, and many new models are proposed every year to achieve better performance. After introducing their specific principles and composition structure, this paper compares three common different deep learning networks named Deep neural network notation (DNN), Convolutional Neural network (CNN) and Recurrent Neural network (RNN), and introduces the recently emerging model named Residual network (Resnet), starting from a specific situation which calls for garbage classification. Moreover, during this experiment, it also gives the method V pipe a try which differs a lot from the former method, and receives good results worth celebrating.

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Section: Deductionmentioning

confidence: 99%

Deep learning networks for microbiology images recognition

Chen

2023

Third International Conference on Artificial Intelligence and Computer Engineering (ICAICE 2022)

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“…Furthermore, the LWF needs additional networks to assist in the construction of new models, it will occupy more space when the quantity of tasks is large. The above shortcomings may be addressed in future research using CNN based networks [11][12][13][14][15] with a pyramidal structure for feature extraction.…”

Section: Problems and Limitationsmentioning

confidence: 99%

Exploration of continual learning based on the comparison and analysis of LWF and EWC

Wang

2023

ACE

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Nowadays, continual learning is seen as one of the important fields of strong artificial intelligence. People focus on it and propose a lot of methods in order to alleviate catastrophic forgetting problem which is serious and essential and cannot be avoided. Among all the methods, EWC and LWF are two typical methods and they have some similarities and differences. This paper adopts comparison method to research the effect of LWF and EWC applied on different datasets and also compares some similar methods like R-EWC and LFL. Meanwhile, some analysis and suggestions about these methods are also given. From the results, both methods improve memory ability. But LWF performs better in testing old knowledge. In contrast, EWC has a stronger ability to learn new knowledge. Both EWC and LWF have some limitations. There are some problems which cause errors for the principle of EWC while for LWF, the confirmation of hyper-parameters has great influence on the experimental results and the method itself has some errors.

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“…However, in recent years, the rapid development of artificial intelligence (AI) technology has provided a promising avenue for handling these fatigue-related problems, such as structural fatigue-resistance design, 21 structural property evaluation, 22 and fatigue fracture recognition. 23 In order to characterize the fatigue state of composites, many feature extraction methods based on deep learning models can be considered, such as the deep neural network (DNN), 22 the convolutional neural network (CNN), 24 and the autoencoder (AE). 25 The notable advantage of the aforementioned methods is the ability to learn the intrinsic features through multi-layered neural networks.…”

Section: Introductionmentioning

confidence: 99%

“…Due to the complex fatigue behavior exhibited by FRPs, 20 addressing numerous engineering issues related to structural fatigue poses inherent challenges. However, in recent years, the rapid development of artificial intelligence (AI) technology has provided a promising avenue for handling these fatigue‐related problems, such as structural fatigue‐resistance design, 21 structural property evaluation, 22 and fatigue fracture recognition 23 . In order to characterize the fatigue state of composites, many feature extraction methods based on deep learning models can be considered, such as the deep neural network (DNN), 22 the convolutional neural network (CNN), 24 and the autoencoder (AE) 25 .…”

Section: Introductionmentioning

confidence: 99%

Fatigue evolution prediction for fiber‐reinforced plastics based on frequency‐wavenumber wavefield of guided wave using deep‐learning model

Huang,

Zhang,

Tao

et al. 2023

Fatigue Fract Eng Mat Struct

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Employing the laser ultrasonic system, information on fatigue evolution can be captured and explicitly stored in the frequency‐wavenumber wavefield of the guided wave. This paper presents a deep‐learning architecture for processing the frequency‐wavenumber wavefield, which comprises two distinct steps: fatigue characterization and evolution prediction. Firstly, the fatigue characterization step employs a convolutional autoencoder (CAE) for compressing the frequency‐wavenumber wavefield and a fully connected network (FCN) for obtaining the fusion fatigue characteristic. Due to the high cost of experimental samples, extensive simulation‐generated wavefields are used to pre‐train the network. Subsequently, the fatigue evolution prediction model based on the latent ordinary differential equation (Latent‐ODE) is trained for the step‐by‐step prediction of fatigue evolution with a small amount of composite fatigue test data. The results validate the effectiveness of the deep‐learning architecture in characterizing fatigue and predicting its evolution, as well as the feasibility of the frequency‐wavenumber wavefield compression of guided wave.

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Artificial intelligence‐assisted fatigue fracture recognition based on morphing and fully convolutional networks

Cited by 10 publications

References 32 publications

Deep learning networks for microbiology images recognition

Deep learning networks for microbiology images recognition

Exploration of continual learning based on the comparison and analysis of LWF and EWC

Fatigue evolution prediction for fiber‐reinforced plastics based on frequency‐wavenumber wavefield of guided wave using deep‐learning model

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