EM-driven unsupervised learning for efficient motion segmentation
This paper presents a CNN-based fully unsupervised method for motion segmentation from optical flow. We assume that the input optical flow can be represented as a piecewise set of parametric motion models, typically, affine or quadratic motion models.The core idea of this work is to leverage the Expectation-Maximization (EM) framework. It enables us to design in a well-founded manner the loss function and the training procedure of our motion segmentation neural network. However, in contrast to the classical iterative EM, once the network is trained, we can provide a segmentation for any unseen optical flow field in a single inference step, with no dependence on the initialization of the motion model parameters since they are not estimated in the inference stage. Different loss functions have been investigated including robust ones. We also propose a novel data augmentation technique on the optical flow field with a noticeable impact on the performance. We tested our motion segmentation network on the DAVIS2016 dataset. Our method outperforms comparable unsupervised methods and is very efficient. Indeed, it can run at 125fps making it usable for real-time applications.
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