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[CS.AI] AnchorPrune: Relevance-Anchored Visual Token Pruning

Published at: 2026-07-10 22:00 Last updated: 2026-07-13 08:26
#algorithm #Machine Learning #optimization

Large vision-language models incur substantial inference costs due to high-resolution inputs that introduce thousands of visual tokens, many of which are redundant for a given query. Existing pruning methods often combine query relevance and token diversity, yet these objectives can conflict under aggressive compression: relevance-driven selection may overconcentrate the budget on correlated local evidence, while diversity-driven selection may suppress indispensable tokens or retain distinct but uninformative regions. We introduce AnchorPrune, a training-free framework that first constructs a protected relevance anchor and then expands it with complementary visual context. AnchorPrune adaptively determines the anchor size from the novelty profile of relevance-ranked tokens, preserving a compact set of query-critical evidence, and allocates the remaining budget through importance-weighted novelty to recover informative, non-redundant context relative to the anchor. This ordered design prevents contextual expansion from displacing indispensable query cues while improving overall visual coverage. AnchorPrune is lightweight, architecture-aware, and requires neither retraining nor model modification. Across image and video vision-language models and benchmarks, it consistently improves the accuracy-efficiency trade-off over training-free baselines, particularly under severe compression. On LLaVA-NeXT-7B, AnchorPrune preserves 97.6% of full-token performance using only 160 of 2,880 visual tokens. These results establish relevance-anchored contextual expansion as an effective principle for efficient multimodal inference. Code is available at GitHub.

Blogger's Review: The introduction of AnchorPrune offers a novel approach to visual token pruning by establishing relevance anchors and expanding visual context, effectively balancing accuracy and efficiency, particularly in high-compression scenarios. Its training-free nature enhances model flexibility in practical applications, making it a noteworthy advancement.

Original Source: https://arxiv.org/abs/2607.07033

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