Abstract
The global community has recognized an increasing amount of pollutants entering oceans and other water bodies as a severe environmental, economic, and social issue. In addition to prevention, one of the key measures in addressing marine pollution is the cleanup of debris already present in marine environments. Deployment of machine learning (ML) and deep learning (DL) techniques can automate marine waste removal, making the cleanup process more efficient. This study examines the performance of six well-known deep convolutional neural networks (CNNs), namely VGG19, InceptionV3, ResNet50, Inception-ResNetV2, DenseNet121, and MobileNetV2, utilized as feature extractors according to three different extraction schemes for the identification and classification of underwater marine debris. We compare the performance of a neural network (NN) classifier trained on top of deep CNN feature extractors when the feature extractor is (1) fixed; (2) fine-tuned on the given task; (3) fixed during the first phase of training and fine-tuned afterward. In general, fine-tuning resulted in better-performing models but is much more computationally expensive. The overall best NN performance showed the fine-tuned Inception-ResNetV2 feature extractor with an accuracy of 91.40% and F1-score 92.08%, followed by fine-tuned InceptionV3 extractor. Furthermore, we analyze conventional ML classifiers’ performance when trained on features extracted with deep CNNs. Finally, we show that replacing NN with a conventional ML classifier, such as support vector machine (SVM) or logistic regression (LR), can further enhance the classification performance on new data.
Highlights
IntroductionDiscarded fishing gear continues to trap and kill marine life
The main goals of this study were to: (1) develop the model for autonomus marine debris identification and classification of different types of marine debris; (2) compare the performance of prominent deep convolutional architectures, including VGG19, InceptionV3, ResNet50, Inception-ResNetV2, DenseNet121, and MobileNetV2, on the task of marine debris classification; (3) investigate different schemes to utilize transfer learning for marine debris classification: fixed extraction of features, fine-tuning, and combination of both; (4) compare the performance of conventional machine learning classifiers trained on feature vectors extracted by deep convolutional architectures
This section compares the final performance of marine debris classifiers when different deep convolutional neural networks (CNNs) architectures are utilized to extract image features
Summary
Discarded fishing gear continues to trap and kill marine life. Animals such as seabirds or turtles often mistake plastic debris with their food due to its similar appearance and odor, which leads to their malnutrition and starvation [2,3]. Identification and the cleanup of marine debris, especially one deep under the water surface, is challenging and expensive. To make the cleanup process more efficient, automatized detection and removal of marine debris is desired. The latter can be realized with the aid of autonomous underwater vehicles (AUVs) and deep-learning-based visual identification of underwater waste
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