Deep neural networks have recently demonstrated state-of-the-art accuracy on public Synthetic Aperture Radar (SAR) Automatic Target Recognition (ATR) benchmark datasets. While attaining competitive accuracy on benchmark datasets is a necessary feature, it is important to characterize other facets of new SAR ATR algorithms. We extend this recent work by demonstrating not only improved state-of-the-art accuracy, but that contemporary deep neural networks can achieve several algorithmic traits beyond competitive accuracy which are necessitated by operational deployment scenarios. First, we employ several saliency map algorithms to provide explainability and insight into understanding black-box classifier decisions. Second, we collect and implement numerous data augmentation routines and training improvements both from the computer vision literature and specific to SAR ATR data in order to further improve model domain adaptation performance from synthetic to measured data, achieving a 99.26% accuracy on SAMPLE validation with a simple network architecture. Finally, we survey model reproducibility and performance variability under domain adaptation from synthetic to measured data, demonstrating potential consequences of training on only synthetic data.
Neural network approaches have periodically been explored in the pursuit of high performing SAR ATR solutions. With deep neural networks (DNNs) now offering many state-of-the-art solutions to computer vision tasks, neural networks are once again being revisited for ATR processing. Here, we characterize and explore a suite of neural network architectural topologies. In doing so, we assess how different architectural approaches impact performance and consider the associated computational costs. This includes characterizing network depth, width, scale, connectivity patterns, as well as convolution layer optimizations. We have explored a suite of architectural topologies applied to both the canonical MSTAR dataset, as well as the more operationally realistic Synthetic and Measured Paired and Labeled Experiment (SAMPLE) dataset. The latter pairs high fidelity computational models of targets with actual measured SAR data. Effectively, this dataset offers the ability to train a DNN on simulated data and test the network performance on measured data. Not only does our in-depth architecture topology analysis offer insight into how different architectural approaches impact performance, but we also have trained DNNs attaining state-of-the-art performance on both datasets. Furthermore, beyond just accuracy, we also assess how efficiently an accelerator architecture executes these neural networks. Specifically, Using an analytical assessment tool, we forecast energy and latency for an edge TPU like architecture. Taken together, this tradespace exploration offers insight into the interplay of accuracy, energy, and latency for executing these networks.
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