Related papers: Unlearning-based Neural Interpretations

Unlearning-based Neural Interpretations

URL: http://arxiv.org/abs/2410.08069v2
Date: Mon, 10 Feb 2025 22:59:07 GMT
Title: Unlearning-based Neural Interpretations
Authors: Ching Lam Choi, Alexandre Duplessis, Serge Belongie,
Abstract summary: We show that current baselines defined using static functions are biased, fragile and manipulable. We propose UNI to compute an (un)learnable, debiased and adaptive baseline by perturbing the input towards an unlearning direction of steepest ascent.
Score: 51.99182464831169
License:
Abstract: Gradient-based interpretations often require an anchor point of comparison to avoid saturation in computing feature importance. We show that current baselines defined using static functions--constant mapping, averaging or blurring--inject harmful colour, texture or frequency assumptions that deviate from model behaviour. This leads to accumulation of irregular gradients, resulting in attribution maps that are biased, fragile and manipulable. Departing from the static approach, we propose UNI to compute an (un)learnable, debiased and adaptive baseline by perturbing the input towards an unlearning direction of steepest ascent. Our method discovers reliable baselines and succeeds in erasing salient features, which in turn locally smooths the high-curvature decision boundaries. Our analyses point to unlearning as a promising avenue for generating faithful, efficient and robust interpretations.

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