A flow feature detection method for modeling pressure distribution around a cylinder in non-uniform flows by using a convolutional neural network

Ye, Shuran; Zhang, Zhen; Song, Xudong; Wang, Yiwei; Yaosong, Chen; Huang, Chenguang

doi:10.1038/s41598-020-61450-z

Cited by 54 publications

(18 citation statements)

References 15 publications

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“…Seperti pada komputer pengujian dan dilatih memakai data set yang memiliki label dan dalam jumlah besar selanjutnya diubah kedalam nilai piksel pada gambar untuk dijadikan representasi internal atau feature vector [21] kemudian selanjutnya pengklasifikasian didapatkan dan digunakan pada deteksi untuk mengklasifikasikan pola pada masukan input [22]. Deep learning merupakan pembelajaran reprensentasi untuk membentuk arsitektur jaringan syaraf tiruan dengan multi lapisan layer [23]. Input layer, hidden layer, dan output layer dalam lapisan deep learning, [24].…”

Section: Pendahuluanunclassified

Klasifikasi Tekstur Kematangan Buah Jeruk Manis Berdasarkan Tingkat Kecerahan Warna dengan Metode Deep Learning Convolutional Neural Network

Yanto

Fimawahib

Supriyanto

et al. 2021

ISI

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Sweet orange is very much consumed by humans because oranges are rich in vitamin C, sweet oranges can be consumed directly to drink. The classification carried out to determine proper (good) and unfit (rotten) oranges still uses manual methods, This classification has several weaknesses, namely the existence of human visual limitations, is influenced by the psychological condition of the observations and takes a long time. One of the classification methods for sweet orange fruit with a computerized system the Convolutional Neural Network (CNN) is algorithm deep learning to the development of the Multilayer Perceptron (MLP) with 100 datasets of sweet orange images, the classification accuracy rate was 97.5184%. the classification was carried out, the result was 67.8221%. Testing of 10 citrus fruit images divided into 5 good citrus images and 5 rotten citrus images at 96% for training 92% for testing which were considered to have been able to classify the appropriateness of sweet orange fruit very well. The graph of the results of the accuracy testing is 0.92 or 92%. This result is quite good, for the RGB histogram display the orange image is good

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Section: Pendahuluanunclassified

Klasifikasi Tekstur Kematangan Buah Jeruk Manis Berdasarkan Tingkat Kecerahan Warna dengan Metode Deep Learning Convolutional Neural Network

Yanto

Fimawahib

Supriyanto

et al. 2021

ISI

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“…For the purposes of computer vision ANNs typically utilize a combination of Convolutional Neural Networks (CNNs) and Fully Connected Layers (FCs). CNNs have proven to be an effective modeling solution for applications ranging from computer vision (image classification, object detection, neural style transfer) [53], [54], cybersecurity [55], time series processing [56], fluid mechanics [57] and general physics challenges [58]. A simplified CNN based process is shown in Fig.…”

Section: Neural Network Convolution Algorithm Overviewmentioning

confidence: 99%

Real World Object Detection Dataset for Quadcopter Unmanned Aerial Vehicle Detection

Pawełczyk

Wojtyra

2020

IEEE Access

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Recent years have shown a noticeable rise in the number of incidents with drones, related to both civilian and military installations. While drone neutralization techniques have become increasingly effective, detection most often relies on professional equipment, which is too expensive to be used for all critical nodes and applications. Therefore, there is a need for drone detection systems that could work on low performance hardware. Its critical component consists of an object detection system. In this article, we introduce a new object detection dataset, built entirely to train computer vision based object detection machine learning algorithms for a task of binary object detection to enable automated, industrial camera based detection of multiple drone objects using camera feed. The dataset expands existing multiclass image classification and object detection datasets (ImageNet, MS-COCO, PASCAL VOC, anti-UAV) with a diversified dataset of drone images. In order to maximize the effectiveness of the model, real world footage was utilized, transformed into images and hand-labelled to create a custom set of 56821 images and 55539 bounding boxes. Additionally, semi-automated labelling was proposed, tested and proved to be very useful for object detection applications. The dataset was divided into train and test subsets for further processing and used to generate 603 easily deployable Haar Cascades as well as 819 high performing Deep Neural Networks based models. They were used to test different object detection methods to determine the long term feasibility of a large scale drone detection system utilizing machine learning algorithms. The study has shown that Haar Cascade can be used as the Minimum Viable Product model for mediocre performance but fails to scale up effectively for a larger dataset compared to the Deep Neural Network model.

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“…In recent years, deep learning has been recognized as a powerful tool in the field of digital image processing, and has also proved promising in addressing various problems in fluid mechanics 20 – 25 . These studies are finding ways to overcome long-lasting problems by applying a deep learning-based methodology to solve governing equations or to improve experimental techniques, which have been shown to enhance model accuracy and save on overall data processing cost, which is dominated by human resources.…”

Section: Introductionmentioning

confidence: 99%

Deep learning-based automated and universal bubble detection and mask extraction in complex two-phase flows

Kim

Park

2021

Sci Rep

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While investigating multiphase flows experimentally, the spatiotemporal variation in the interfacial shape between different phases must be measured to analyze the transport phenomena. For this, numerous image processing techniques have been proposed, showing good performance. However, they require trial-and-error optimization of thresholding parameters, which are not universal for all experimental conditions; thus, their accuracy is highly dependent on human experience, and the overall processing cost is high. Motivated by the remarkable improvements in deep learning-based image processing, we trained the Mask R-CNN to develop an automated bubble detection and mask extraction tool that works universally in gas–liquid two-phase flows. The training dataset was rigorously optimized to improve the model performance and delay overfitting with a finite amount of data. The range of detectable bubble size (particularly smaller bubbles) could be extended using a customized weighted loss function. Validation with different bubbly flows yields promising results, with AP50reaching 98%. Even while testing with bubble-swarm flows not included in the training set, the model detects more than 95% of the bubbles, which is equivalent or superior to conventional image processing methods. The pure processing speed for mask extraction is more than twice as fast as conventional approaches, even without counting the time required for tedious threshold parameter tuning. The present bubble detection and mask extraction tool is available online (https://github.com/ywflow/BubMask).

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A flow feature detection method for modeling pressure distribution around a cylinder in non-uniform flows by using a convolutional neural network

Cited by 54 publications

References 15 publications

Klasifikasi Tekstur Kematangan Buah Jeruk Manis Berdasarkan Tingkat Kecerahan Warna dengan Metode Deep Learning Convolutional Neural Network

Klasifikasi Tekstur Kematangan Buah Jeruk Manis Berdasarkan Tingkat Kecerahan Warna dengan Metode Deep Learning Convolutional Neural Network

Real World Object Detection Dataset for Quadcopter Unmanned Aerial Vehicle Detection

Deep learning-based automated and universal bubble detection and mask extraction in complex two-phase flows

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