Abstract
Fine-grained vehicle classification from images, also known as Vehicle Make and Model Recognition (VMMR), has become an important research topic in the last years, with a growing number of scientific contributions in multiple application areas, such as autonomous vehicles, surveillance systems, traffic monitoring and management, among others. Recent techniques based on deep learning have proven to be very effective in addressing this problem. So effective that, based on the state-of-the-art results (above 95% accuracy), it would seem that the problem is practically solved. However, our main hypothesis is that the existing datasets to date have limited variability, which precludes good and unbiased generalisation of the models trained with them. In particular, it is observed that the test datasets are very similar in nature to those used for training and validation which makes these benchmarks prone to dataset bias and to overfitting. When these systems are tested with more challenging data or data from different datasets performance degrades considerably. In this paper, on the one hand, we evaluate state-of-the-art deep learning models to perform fine-grained vehicle classification and explore multiple training techniques, such as curriculum learning or weighted losses, to mitigate the bias between different makes and models and to assess the limits of current approaches. On the other hand, we analyse the existing datasets, present an additional dataset from a challenging scenario, and merge all the data into a cross-dataset that includes common samples and classes from the existing datasets. In this way, we can evaluate geographical, make and model biases, and performance and generalisation capabilities from a more realistic perspective. The obtained results suggest that we are still far from accurate and unbiased vehicle make and model recognition in realistic traffic and driving scenarios.
Highlights
F INE-GRAINED vehicle classification consists in the classification of vehicles according to make and model and even differentiating between different versions of a particular model
We aim to study the applicability of curriculum learning techniques to the fine-grained vehicle classification problem and evaluate its performance
If we look at the results of Vehicle Make and Model Recognition (VMMR)-db Models in Fig. 7, we can see that this problem is considerably greater and, even though the top1 accuracy is 94.46%, there is a considerable number of classes with poor performance
Summary
F INE-GRAINED vehicle classification consists in the classification of vehicles according to make and model and even differentiating between different versions of a particular model (ultra-fine-grained classification) This task is especially useful when used in combination with other applications such as license plate recognition systems to detect if a vehicle is driving with a fake number plate, or in a public car park to detect an attempted theft. Regarding number plate recognition systems, this information can be used to obtain vehicle data and solve the vehicle classification task, but this approach is vulnerable to recognition errors, license plate swap, and license plate information is not always available. For this reason, a robust system that is able to classify make and model efficiently could be extremely useful.
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