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Effectiveness of Transfer Learning with Light-weight Architecture for Covid-19 Imaging

Effectiveness of Transfer Learning with Light-weight Architecture for Covid-19 Imaging PDF Author: Rajesh Godasu
Publisher:
ISBN:
Category :
Languages : en
Pages : 0

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Book Description
"Transfer learning has emerged as a pivotal technique in deep learning, allowing pre-trained models to be fine-tuned for novel tasks. This has often led to enhanced performance and reduced training time. Lightweight architectures known for their efficiency and speed, without compromising accuracy complement this technique. These two techniques combined address the issues of limited availability of training data and the requirement of high computational resources. Numerous researchers delved into these methods to address the challenges posed by the Covid-19 pandemic. Within this framework, our study sought to evaluate the multi-stage transfer learning method across several dataset sizes and truncated versions of the lightweight MobileNetV2 architecture for medical image classification. Initially, an exhaustive literature review was conducted to present the latest advancements in transfer learning and lightweight architecture applications for COVID-19 image classification. Additionally, this study explores the trade-offs between finetuning and dataset size in a multi-stage transfer learning system using a lightweight architecture. Lastly, in this study, we aim to analyze the performance of truncated lightweight models against different training dataset sizes in a multi-stage transfer learning framework. The results of this study significantly enhance the knowledge in this specialized research area. The most popular lightweight architectures were identified, and we found that standard CNNs can be truncated without losing performance. The study also established that mid-sized datasets and freezing 90 to 95 layers yield the best performance on the target task. Furthermore, the study highlights a key trade-off in stage one transfer learning: smaller datasets require more extensive layer training, while larger datasets need fewer re-trained layers for optimal performance. Also, beyond a certain dataset size, deeper fine-tuning does not lead to improved accuracy. Finally, we established that complex models tolerate more frozen layers, maintaining adequate learning capacity. The findings support the idea that while more complex models demonstrate higher accuracy, simpler models perform competitively. Moreover, the impact of model complexity is reduced on target performance with small-size datasets. These insights underscore the efficiency of multi-stage transfer learning with lightweight models, especially when pre-trained models are applied to new datasets. The present research adds to the improvement of the effectiveness of medical expert systems while also reducing the burden on healthcare professionals." -- Abstract (leaf iv)

Effectiveness of Transfer Learning with Light-weight Architecture for Covid-19 Imaging

Effectiveness of Transfer Learning with Light-weight Architecture for Covid-19 Imaging PDF Author: Rajesh Godasu
Publisher:
ISBN:
Category :
Languages : en
Pages : 0

Get Book Here

Book Description
"Transfer learning has emerged as a pivotal technique in deep learning, allowing pre-trained models to be fine-tuned for novel tasks. This has often led to enhanced performance and reduced training time. Lightweight architectures known for their efficiency and speed, without compromising accuracy complement this technique. These two techniques combined address the issues of limited availability of training data and the requirement of high computational resources. Numerous researchers delved into these methods to address the challenges posed by the Covid-19 pandemic. Within this framework, our study sought to evaluate the multi-stage transfer learning method across several dataset sizes and truncated versions of the lightweight MobileNetV2 architecture for medical image classification. Initially, an exhaustive literature review was conducted to present the latest advancements in transfer learning and lightweight architecture applications for COVID-19 image classification. Additionally, this study explores the trade-offs between finetuning and dataset size in a multi-stage transfer learning system using a lightweight architecture. Lastly, in this study, we aim to analyze the performance of truncated lightweight models against different training dataset sizes in a multi-stage transfer learning framework. The results of this study significantly enhance the knowledge in this specialized research area. The most popular lightweight architectures were identified, and we found that standard CNNs can be truncated without losing performance. The study also established that mid-sized datasets and freezing 90 to 95 layers yield the best performance on the target task. Furthermore, the study highlights a key trade-off in stage one transfer learning: smaller datasets require more extensive layer training, while larger datasets need fewer re-trained layers for optimal performance. Also, beyond a certain dataset size, deeper fine-tuning does not lead to improved accuracy. Finally, we established that complex models tolerate more frozen layers, maintaining adequate learning capacity. The findings support the idea that while more complex models demonstrate higher accuracy, simpler models perform competitively. Moreover, the impact of model complexity is reduced on target performance with small-size datasets. These insights underscore the efficiency of multi-stage transfer learning with lightweight models, especially when pre-trained models are applied to new datasets. The present research adds to the improvement of the effectiveness of medical expert systems while also reducing the burden on healthcare professionals." -- Abstract (leaf iv)

Deep Learning Techniques for the Radiological Imaging of COVID-19

Deep Learning Techniques for the Radiological Imaging of COVID-19 PDF Author: Robert Hertel
Publisher:
ISBN:
Category :
Languages : en
Pages : 0

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Book Description
The AI research community has recently been intensely focused on diagnosing COVID19 by applying deep learning technology to the X-ray scans taken of COVID-19 patients. COVID-19 shares many of the same imaging characteristics as other common forms of bacterial and viral pneumonia. Differentiating COVID-19 from other common pulmonary infections, therefore, is a non-trivial task. While RT-PCR tests are the first viral tests commonly performed on COVID-19 patients, radiological tests are often reserved for further study of the illness in patients presenting with increased risk factors. To help offset what commonly requires hours of tedious manual annotation, our work uses Convolutional Neural Networks and other machine learning techniques to decrease the time radiologists spend interpreting COVID-19 radiological scans. Deep learning experts commonly use transfer learning to offset the small number of images typically available in medical imaging tasks. Our first study's architecture included a deep neural network that was pretrained on over one hundred thousand X-ray images. We incorporated this architecture into two models with the purpose of diagnosing COVID-19. The experimental results demonstrate the robustness of our deep learning models, ultimately achieving sensitivities of 95% and 96% for our three-class and two-class models respectively. To help further clarify the diagnosis of suspected COVID-19 patients, in our second study, we have designed a deep learning pipeline with a segmentation module and ensemble classifier. After performing a thorough comparative analysis, we demonstrate that our best model can successfully obtain an accuracy of 91% and a sensitivity of 92%. Following a detailed description of our deep learning pipeline, we present the strengths and shortcomings of our approach and compare our model with other similarly constructed models. Finally, we conclude with possible future directions for this research.

A Deep Transfer Learning Model with Classical Data Augmentation and CGAN to Detect COVID-19 from Chest CT Radiography Digital Images

A Deep Transfer Learning Model with Classical Data Augmentation and CGAN to Detect COVID-19 from Chest CT Radiography Digital Images PDF Author: Mohamed Loey
Publisher: Infinite Study
ISBN:
Category : Medical
Languages : en
Pages : 17

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Book Description
In this study, five different deep convolutional neural network-based models (AlexNet, VGGNet16, VGGNet19, GoogleNet, and ResNet50) have been selected for the investigation to detect the coronavirus infected patient using chest CT radiographs digital images. The classical data augmentations along with CGAN improve the performance of classification in all selected deep transfer models. The Outcomes show that ResNet50 is the most appropriate classifier to detect the COVID-19 from chest CT dataset using the classical data augmentation and CGAN with testing accuracy of 82.91%.

A Survey on Deep Transfer Learning and Edge Computing for Mitigating the COVID-19 Pandemic

A Survey on Deep Transfer Learning and Edge Computing for Mitigating the COVID-19 Pandemic PDF Author: Abu Su an
Publisher: Infinite Study
ISBN:
Category : Medical
Languages : en
Pages : 30

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Book Description
Global Health sometimes faces pandemics as are currently facing COVID-19 disease. The spreading and infection factors of this disease are very high. A huge number of people from most of the countries are infected within six months from its rst report of appearance and it keeps spreading. The required systems are not ready up to some stages for any pandemic; therefore, mitigation with existing capacity becomes necessary. On the other hand, modern-era largely depends on Artificial Intelligence(AI) including Data Science; Deep Learning(DL) is one of the current ag-bearer of these techniques. It could use to mitigate COVID-19 like pandemics in terms of stop spread, diagnosis of the disease, drug & vaccine discovery, treatment, and many more.

Within the Lack of Chest COVID-19 X-ray Dataset: A Novel Detection Model Based on GAN and Deep Transfer Learning

Within the Lack of Chest COVID-19 X-ray Dataset: A Novel Detection Model Based on GAN and Deep Transfer Learning PDF Author: Mohamed Loey
Publisher: Infinite Study
ISBN:
Category : Mathematics
Languages : en
Pages : 19

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Book Description
The coronavirus (COVID-19) pandemic is putting healthcare systems across the world under unprecedented and increasing pressure according to theWorld Health Organization (WHO). With the advances in computer algorithms and especially Artificial Intelligence, the detection of this type of virus in the early stages will help in fast recovery and help in releasing the pressure off healthcare systems.

COVID-19 X-ray Image Classification

COVID-19 X-ray Image Classification PDF Author: Julian Albert Aviles Ortiz
Publisher:
ISBN:
Category :
Languages : en
Pages : 36

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Book Description
A coronavirus pandemic spread throughout the world starting in 2019. This event led to the release of X-ray image data used in the diagnosis of COVID-19, the disease caused by the coronavirus. Machine learning techniques based on convolutional neural networks have been developed for image classification, but these models require large amounts of data. Due to the ongoing nature of the pandemic, the size of COVID-19 X-ray image datasets is still relatively small. A method of image classification based on transfer learning is explored to leverage the smaller datasets currently available. Based on VGG16, an earlier image classification convolutional neural network, the model achieves accurate predictions. An application of Grad-CAM is also explored to aid in interpretation.

A Study of the Neutrosophic Set Significance on Deep Transfer Learning Models: An Experimental Case on a Limited COVID-19 Chest X-Ray Dataset

A Study of the Neutrosophic Set Significance on Deep Transfer Learning Models: An Experimental Case on a Limited COVID-19 Chest X-Ray Dataset PDF Author: Nour Eldeen M. Khalifa
Publisher: Infinite Study
ISBN:
Category : Mathematics
Languages : en
Pages : 17

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Book Description
Coronavirus, also known as COVID-19, has spread to several countries around the world. It was announced as a pandemic disease by The World Health Organization (WHO) in 2020 for its devastating impact on humans. With the advancements in computer science algorithms, the detection of this type of virus in the early stages is urgently needed for the fast recovery of patients. In this paper, a study of neutrosophic set significance on deep transfer learning models over a limited COVID-19 chest x-ray dataset will be presented. The study relies on neutrosophic set theory, as it shows a huge potential for solving many computers problems related to the detection, and the classification domains.

Data-Driven Clinical Decision-Making Using Deep Learning in Imaging

Data-Driven Clinical Decision-Making Using Deep Learning in Imaging PDF Author: M. F. Mridha
Publisher: Springer Nature
ISBN: 9819739667
Category :
Languages : en
Pages : 277

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Book Description

Computational Modelling and Imaging for SARS-CoV-2 and COVID-19

Computational Modelling and Imaging for SARS-CoV-2 and COVID-19 PDF Author: S. Prabha
Publisher: CRC Press
ISBN: 1000439356
Category : Medical
Languages : en
Pages : 161

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Book Description
The aim of this book is to present new computational techniques and methodologies for the analysis of the clinical, epidemiological and public health aspects of SARS-CoV-2 and COVID-19 pandemic. The book presents the use of soft computing techniques such as machine learning algorithms for analysis of the epidemiological aspects of the SARS-CoV-2. This book clearly explains novel computational image processing algorithms for the detection of COVID-19 lesions in lung CT and X-ray images. It explores various computational methods for computerized analysis of the SARS-CoV-2 infection including severity assessment. The book provides a detailed description of the algorithms which can potentially aid in mass screening of SARS-CoV-2 infected cases. Finally the book also explains the conventional epidemiological models and machine learning techniques for the prediction of the course of the COVID-19 epidemic. It also provides real life examples through case studies. The book is intended for biomedical engineers, mathematicians, postgraduate students; researchers; medical scientists working on identifying and tracking infectious diseases.

Deep Learning in Medical Image Analysis

Deep Learning in Medical Image Analysis PDF Author: Gobert Lee
Publisher: Springer Nature
ISBN: 3030331288
Category : Medical
Languages : en
Pages : 184

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Book Description
This book presents cutting-edge research and applications of deep learning in a broad range of medical imaging scenarios, such as computer-aided diagnosis, image segmentation, tissue recognition and classification, and other areas of medical and healthcare problems. Each of its chapters covers a topic in depth, ranging from medical image synthesis and techniques for muskuloskeletal analysis to diagnostic tools for breast lesions on digital mammograms and glaucoma on retinal fundus images. It also provides an overview of deep learning in medical image analysis and highlights issues and challenges encountered by researchers and clinicians, surveying and discussing practical approaches in general and in the context of specific problems. Academics, clinical and industry researchers, as well as young researchers and graduate students in medical imaging, computer-aided-diagnosis, biomedical engineering and computer vision will find this book a great reference and very useful learning resource.