Empirical Evidence for Simply Connected Decision Regions in Image Classifiers
Abstract
Decision regions in deep neural networks exhibit simple connectivity, demonstrated through quad-mesh filling procedures and Coons patch analysis.
Understanding the topology of decision regions is central to explaining the inner workings of deep neural networks. Prior empirical work has provided evidence that these regions are path connected. We study a stronger topological question: whether closed loops inside a decision region can be contracted without leaving that region. To this end, we propose an iterative quad-mesh filling procedure that constructs a finite-resolution label-preserving surface bounded by a given loop and lying entirely within the same decision region. We further connect this construction to natural Coons patches in order to quantify its deviation from a canonical geometric interpolation of the loop. By evaluating our method across several modern image-classification models, we provide empirical evidence supporting the hypothesis that decision regions in deep neural networks are not only path connected, but also simply connected.
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We empirically investigate whether image-classifier decision regions appear simply connected at finite resolution.
Prior work has studied path-connectedness of decision regions. This paper asks a stronger topological question: given four natural images with the same predicted label, can the loop they form be filled by a label-preserving surface?
Our procedure recursively constructs and verifies a quad-mesh surface using grid sampling and local decision-boundary repair. Across several ImageNet classifiers, the experiments provide empirical evidence consistent with the hypothesis that decision regions are simply connected.
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