The Effectiveness of Image Augmentation in Deep Learning Networks for Detecting COVID-19: A Geometric Transformation Perspective

Elgendi, Mohamed; Nasir, Muhammad Umer; Tang, Qunfeng; Smith, David L.; Grenier, John Paul; Batte, Catherine; Spieler, Bradley; Leslie, William D.; Menon, Carlo; Fletcher, Richard Ribbon; Howard, Newton; Ward, Rabab K.; Parker, William; Nicolaou, Savvas

doi:10.3389/fmed.2021.629134

Cited by 74 publications

(43 citation statements)

References 43 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Data augmentation can improve model generalization by increasing the variations in the training set [ 73 ]. Image processing techniques, including standardization, normalization, reorientation, registration, and histogram matching, can be used to harmonize images sourced from different origins and remove domain bias.…”

Section: Key Considerationsmentioning

confidence: 99%

Key Technology Considerations in Developing and Deploying Machine Learning Models in Clinical Radiology Practice

Kulkarni¹,

Gawali²,

Kharat³

2021

JMIR Med Inform

View full text Add to dashboard Cite

The use of machine learning to develop intelligent software tools for the interpretation of radiology images has gained widespread attention in recent years. The development, deployment, and eventual adoption of these models in clinical practice, however, remains fraught with challenges. In this paper, we propose a list of key considerations that machine learning researchers must recognize and address to make their models accurate, robust, and usable in practice. We discuss insufficient training data, decentralized data sets, high cost of annotations, ambiguous ground truth, imbalance in class representation, asymmetric misclassification costs, relevant performance metrics, generalization of models to unseen data sets, model decay, adversarial attacks, explainability, fairness and bias, and clinical validation. We describe each consideration and identify the techniques used to address it. Although these techniques have been discussed in prior research, by freshly examining them in the context of medical imaging and compiling them in the form of a laundry list, we hope to make them more accessible to researchers, software developers, radiologists, and other stakeholders.

show abstract

Section: Key Considerationsmentioning

confidence: 99%

Key Technology Considerations in Developing and Deploying Machine Learning Models in Clinical Radiology Practice

Kulkarni¹,

Gawali²,

Kharat³

2021

JMIR Med Inform

View full text Add to dashboard Cite

show abstract

“…But many authors utilise small private dataset together with larger public datasets. An exemplary case is the use of private datasets as external test data, therewith assessing the transportability of models trained on (merged) public datasets to the private test data population and thus to the underlying hospital setting ( Park, Kim, Oh, Seo, Lee, Kim, Moon, Lim, Ye , Kim, Park, Oh, Seo, Lee, Kim, Moon, Lim, Ye , Elgendi, Nasir, Tang, Smith, Grenier, Batte, Spieler, Leslie, Menon, Fletcher, et al., 2021 , Robinson, Trivedi, Blazes, Ortiz, Desbiens, Gupta, Dodhia, Bhatraju, Liles, Lee, et al., 2021 ).…”

Section: Resultsmentioning

confidence: 99%

Public Covid-19 X-ray datasets and their impact on model bias – A systematic review of a significant problem

Cruz

Bossa

Sölter

et al. 2021

Medical Image Analysis

View full text Add to dashboard Cite

show abstract

“…This could prove useful for classification problems where there is a well-defined loss/cost for misclassified samples. (Elgendi et al, 2021) proposes a solution to the second challenge by introducing and comparing four data augmentation methods for artificially increasing the number of training samples of X-ray images, while performing Covid-19 pneumonia detection using a CNN. The methods uses combinations of random rotations, shear, translation, horizontal-and vertical flipping among other data augmentation methods.…”

Section: Introductionmentioning

confidence: 99%

Deep Learning-based Anomaly Detection on X-ray Images of Fuel Cell Electrodes

Jensen,

Moeslund,

Andreasen

2022

Preprint

View full text Add to dashboard Cite

Anomaly detection in X-ray images has been an active and lasting research area in the last decades, especially in the domain of medical X-ray images. For this work, we created a real-world labeled anomaly dataset, consisting of 16-bit X-ray image data of fuel cell electrodes coated with a platinum catalyst solution and perform anomaly detection on the dataset using a deep learning approach. The dataset contains a diverse set of anomalies with 11 identified common anomalies where the electrodes contain e.g. scratches, bubbles, smudges etc. We experiment with 16-bit image to 8-bit image conversion methods to utilize pre-trained Convolutional Neural Networks as feature extractors (transfer learning) and find that we achieve the best performance by maximizing the contrasts globally across the dataset during the 16-bit to 8-bit conversion, through histogram equalization. We group the fuel cell electrodes with anomalies into a single class called abnormal and the normal fuel cell electrodes into a class called normal, thereby abstracting the anomaly detection problem into a binary classification problem. We achieve a balanced accuracy of 85.18%. The anomaly detection is used by the company, Serenergy, for optimizing the time spend on the quality control of the fuel cell electrodes.

show abstract

The Effectiveness of Image Augmentation in Deep Learning Networks for Detecting COVID-19: A Geometric Transformation Perspective

Cited by 74 publications

References 43 publications

Key Technology Considerations in Developing and Deploying Machine Learning Models in Clinical Radiology Practice

Key Technology Considerations in Developing and Deploying Machine Learning Models in Clinical Radiology Practice

Public Covid-19 X-ray datasets and their impact on model bias – A systematic review of a significant problem

Deep Learning-based Anomaly Detection on X-ray Images of Fuel Cell Electrodes

Contact Info

Product

Resources

About