Sparse autoencoders applied to Neural Quantum States extract unsupervised features correlating with and causally steering physical observables such as order parameters while preserving variational energy.
Scaling Monosemanticity: Extracting Interpretable Features from Claude 3 Sonnet
2 Pith papers cite this work. Polarity classification is still indexing.
abstract
We demonstrate that sparse autoencoders can extract interpretable features from Claude 3 Sonnet, a production-scale language model, addressing the open question of whether dictionary learning methods scale beyond small transformers. We trained sparse autoencoders with up to 34 million features on the model's middle layer residual stream, using scaling laws to guide hyperparameter selection. The resulting features are multilingual and multimodal (generalizing to images despite text-only training), respond to both concrete instances and abstract discussions of concepts, and can be used to steer model behavior in ways consistent with their interpretations. We find features corresponding to famous entities and locations, as well as more abstract concepts like sarcasm or errors in code. We also identify features relevant to ways in which language models might cause harm--including features representing deception, power-seeking, sycophancy, and bias--and show that these causally influence model outputs when manipulated. Additionally, we conduct analyses of feature interpretability, geometry, and computational function. However, significant limitations remain: our suite of features is incomplete, and we lack rigorous methods for evaluating whether our features faithfully capture model computations.
years
2026 2verdicts
UNVERDICTED 2representative citing papers
HydraHead hybridizes full and linear attention along the head dimension via interpretability-driven selection and scale-normalized fusion, matching layer-wise hybrids at higher linear ratios after 15B-token training.
citing papers explorer
-
HydraHead: From Head-Level Functional Heterogeneity to Specialized Attention Hybridization
HydraHead hybridizes full and linear attention along the head dimension via interpretability-driven selection and scale-normalized fusion, matching layer-wise hybrids at higher linear ratios after 15B-token training.