Enhancing Reproducibility and Replicability in Remote Sensing Deep Learning Research and Practice
Abstract
:1. Introduction
2. Issues and Needs
3. Recommendations and Best Practices
- Where appropriate and available, data originator, sensor and platform, and product level information should be indicated along with collection date(s) and data identifiers. Pre-processing operations and pipelines should be documented including georeferencing and orthorectification, coordinate transformations, resampling methods, spatial and spectral enhancements, pan sharpening, and contrast enhancements.
- Whenever possible, code should be made publicly available using an academic or code repository. The code should be well commented and explained, and version numbers of used software, development environments, code libraries, and/or dependencies should be provided. If it is not possible to make code available, then it is of increased importance to clearly document the methods, data, processing, and algorithm architecture in associated research articles and/or other documentation.
- Algorithms should be well explained and documented in articles and reports. This should include the base algorithm or architectures used, original citations for the method, and descriptions of any augmentations to the base architecture (e.g., adding batch normalization, using a different activation function, modifying the number of convolutional blocks, or changing the number of learned kernels). Readers should be able to use the described methods to augment the base architecture to reproduce the augmented algorithm used in the study or project.
- Random seeds can be set to enhance reproducibility. However, needs and methods vary between frameworks, as described by Alahmari et al. [37]. Users should consult documentation to determine how to appropriately set random seeds to obtain deterministic models or reproducible results. However, this may not be possible in all software or framework environments. As an alternative, researchers could run multiple, randomly initialized models, and report the variability in the final model results, which may be especially useful when comparing algorithms, methods, or feature spaces. However, this may not be possible given the computational costs of running multiple model iterations.
- The entire training process should be clearly described, including input chip size, number of training samples, number of validation samples, batch size, epochs, callbacks and/or schedulers used, optimization algorithm used and associated parameters (e.g., learning rate), and loss metric implemented.
- Training, validation, and testing data should be provided if possible. The number of available chips and how chips and associated labels were generated from larger image extents should be clearly documented. The methods used to partition the available chips into training, validation, and testing sets should be well explained. The geographic extent of the dataset(s) and source data should be well described and referenced. Any processing applied, such as rescaling pixel values or applying normalization, requires explanation. Other researchers and analyst should be able to reproduce the experimental workflow to obtain the same values and tensors used in the original analysis. If it is not possible to make the training data available, it is still important to clearly document the workflow used since others may need to implement the same methods in order to apply the algorithm to new data.
- Studies must be carefully designed so as not to introduce data leakage, which can severely impact replicability and even invalidate model assessment results [46]. Researchers should pay special attention to data partitioning methods, issues of temporal and spatial autocorrelation between samples in the data partitions, and not incorporating testing data into preprocessing and feature selection workflows.
- If transfer learning is used to initialize the model weights, the source of the weights should be explained, such as the image dataset used. Moreover, it is necessary to explain what weights in the model were updated during the training process and which were not. If some weights were only updated during a subset of training epochs, such as those associated with the CNN backbone used to develop feature maps, this should also be explained and documented.
- All data augmentations or transformations applied to increase the size of the training dataset and potentially reduce overfitting need to be explained including what transformations were used (e.g., blur, sharpen, brighten, contrast shifts, flip, rotate, etc.) and the probabilities of applying them. For increased transparency, augmented data can be written to files and provided with the original chips.
- Methods used to validate and assess models should be explained such that they can be reproduced. When evaluating models, it is also important that researchers adhere to defendable methods for assessing model performance and the accuracy of products, such as those suggested by Maxwell et al. [22,23].
4. Conclusions
Author Contributions
Funding
Data Availability Statement
Acknowledgments
Conflicts of Interest
References
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Topic | Title | Citation | Year |
---|---|---|---|
Selecting a Loss Metric | “Loss odyssey in medical image segmentation” | Ma et al. [72] | 2021 |
Learning Rate, Schedulers, and Hyperparameters | “Cyclical learning rates for training neural networks” | Smith [73] | 2017 |
“A disciplined approach to neural network hyper-parameters: Part 1–learning rate, batch size, momentum, and weight decay” | Smith [74] | 2018 | |
“Demystifying learning rate policies for high accuracy training of deep neural networks” | Wu et al. [75] | 2019 | |
Data Leakage | “Leakage and the reproducibility crisis in ML-based science” | Kapoor and Narayannan [46] | 2022 |
Accuracy Assessment Best Practices | “Classification assessment methods” | Tharwat [76] | 2020 |
“Accuracy assessment in convolutional neural network-based deep learning remote sensing studies—Part 1: literature review” | Maxwell et al. [22] | 2021 | |
“Accuracy assessment in convolutional neural network-based deep learning remote sensing studies—Part 2: recommendations and best practices” | Maxwell et al. [23] | 2021 | |
Combating Overfitting | “Batch normalization: Accelerating deep network training by reducing internal covariate shift” | Ioffe and Szegedy [40] | 2015 |
“Understanding batch normalization” | Bjorck et al. [39] | 2018 | |
“A survey on image data augmentation for deep learning” | Shorten and Khoshgoftaar [45] | ||
“Dropout vs. batch normalization: an empirical study of their impact to deep learning” | Garbin et al. [38] | 2020 |
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Maxwell, A.E.; Bester, M.S.; Ramezan, C.A. Enhancing Reproducibility and Replicability in Remote Sensing Deep Learning Research and Practice. Remote Sens. 2022, 14, 5760. https://doi.org/10.3390/rs14225760
Maxwell AE, Bester MS, Ramezan CA. Enhancing Reproducibility and Replicability in Remote Sensing Deep Learning Research and Practice. Remote Sensing. 2022; 14(22):5760. https://doi.org/10.3390/rs14225760
Chicago/Turabian StyleMaxwell, Aaron E., Michelle S. Bester, and Christopher A. Ramezan. 2022. "Enhancing Reproducibility and Replicability in Remote Sensing Deep Learning Research and Practice" Remote Sensing 14, no. 22: 5760. https://doi.org/10.3390/rs14225760
APA StyleMaxwell, A. E., Bester, M. S., & Ramezan, C. A. (2022). Enhancing Reproducibility and Replicability in Remote Sensing Deep Learning Research and Practice. Remote Sensing, 14(22), 5760. https://doi.org/10.3390/rs14225760