Please use this identifier to cite or link to this item: http://hdl.handle.net/10397/119597
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Title: EAP-GP : mitigating saturation effect in gradient-based automated circuit identification
Authors: Zhang, L
Dong, W
Zhang, Z
Yang, S
Hu, L
Liu, N 
Zhou, P
Wang, D
Issue Date: 2025
Source: In D Belgrave, C Zhang, H Lin, R Pascanu, P Koniusz, M Ghassemi & N Chen (Eds.), Advances in Neural Information Processing Systems 38. NeurIPS 2025 [Poster Presentation]. https://neurips.cc/virtual/2025/loc/san-diego/poster/116294
Abstract: Understanding the internal mechanisms of transformer-based language models remains challenging. Mechanistic interpretability based on circuit discovery aims to reverse engineer neural networks by analyzing their internal processes at the level of computational subgraphs. In this paper, we revisit existing gradient-based circuit identification methods and find that their performance is either affected by the zero-gradient problem or saturation effects, where edge attribution scores become insensitive to input changes, resulting in noisy and unreliable attribution evaluations for circuit components. To address the saturation effect, we propose Edge Attribution Patching with GradPath (EAP-GP), EAP-GP introduces an integration path, starting from the input and adaptively following the direction of the difference between the gradients of corrupted and clean inputs to avoid the saturated region. This approach enhances attribution reliability and improves the faithfulness of circuit identification. We evaluate EAP-GP on 6 datasets using GPT-2 Small, GPT-2 Medium, and GPT-2 XL. Experimental results demonstrate that EAP-GP outperforms existing methods in circuit faithfulness, achieving improvements up to 17.7%. Comparisons with manually annotated ground-truth circuits demonstrate that EAP-GP achieves precision and recall comparable to or better than previous approaches, highlighting its effectiveness in identifying accurate circuits.
Description: The Thirty-ninth Annual Conference on Neural Information Processing Systems, NeurIPS 2025, San Diego, USA, Dec 01 2025
Rights: Posted with permission of the author.
Appears in Collections:Conference Paper

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