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Main Authors: Fraser, Sandy, Wielopolski, Patryk
Format: Preprint
Published: 2025
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Online Access:https://arxiv.org/abs/2512.12469
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author Fraser, Sandy
Wielopolski, Patryk
author_facet Fraser, Sandy
Wielopolski, Patryk
contents We introduce Sparse Concept Anchoring, a method that biases latent space to position a targeted subset of concepts while allowing others to self-organize, using only minimal supervision (labels for <0.1% of examples per anchored concept). Training combines activation normalization, a separation regularizer, and anchor or subspace regularizers that attract rare labeled examples to predefined directions or axis-aligned subspaces. The anchored geometry enables two practical interventions: reversible behavioral steering that projects out a concept's latent component at inference, and permanent removal via targeted weight ablation of anchored dimensions. Experiments on structured autoencoders show selective attenuation of targeted concepts with negligible impact on orthogonal features, and complete elimination with reconstruction error approaching theoretical bounds. Sparse Concept Anchoring therefore provides a practical pathway to interpretable, steerable behavior in learned representations.
format Preprint
id arxiv_https___arxiv_org_abs_2512_12469
institution arXiv
publishDate 2025
record_format arxiv
spellingShingle Sparse Concept Anchoring for Interpretable and Controllable Neural Representations
Fraser, Sandy
Wielopolski, Patryk
Machine Learning
I.2.6
We introduce Sparse Concept Anchoring, a method that biases latent space to position a targeted subset of concepts while allowing others to self-organize, using only minimal supervision (labels for <0.1% of examples per anchored concept). Training combines activation normalization, a separation regularizer, and anchor or subspace regularizers that attract rare labeled examples to predefined directions or axis-aligned subspaces. The anchored geometry enables two practical interventions: reversible behavioral steering that projects out a concept's latent component at inference, and permanent removal via targeted weight ablation of anchored dimensions. Experiments on structured autoencoders show selective attenuation of targeted concepts with negligible impact on orthogonal features, and complete elimination with reconstruction error approaching theoretical bounds. Sparse Concept Anchoring therefore provides a practical pathway to interpretable, steerable behavior in learned representations.
title Sparse Concept Anchoring for Interpretable and Controllable Neural Representations
topic Machine Learning
I.2.6
url https://arxiv.org/abs/2512.12469