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We use GPT-4 to automatically write explanations for the behavior of neurons in large language models and to score those explanations. We release a dataset of these (imperfect) explanations and scores for every neuron in GPT-2.

Language models have become more capable and more broadly deployed, but our understanding of how they work internally is still very limited. For example, it might be difficult to detect from their outputs whether they use biased heuristics or engage in deception. Interpretability research aims to uncover additional information by looking inside the model.

One simple approach to interpretability research is to first understand what the individual components (neurons and attention heads) are doing. This has traditionally required humans to manually(opens in a new window) inspect neurons(opens in a new window) to figure out what features of the data they represent. This process doesn’t scale well: it’s hard to apply it to neural networks with tens or hundreds of billions of parameters. We propose an automated process that uses GPT-4 to produce and score natural language explanations of neuron behavior and apply it to neurons in another language model.

This work is part of the third pillar of our approach to alignment research: we want to automate the alignment research work itself. A promising aspect of this approach is that it scales with the pace of AI development. As future models become increasingly intelligent and helpful as assistants, we will find better explanations.

How it works

Our methodology consists of running 3 steps on every neuron.


What we found

Using our scoring methodology, we can start to measure how well our techniques work for different parts of the network and try to improve the technique for parts that are currently poorly explained. For example, our technique works poorly for larger models, possibly because later layers are harder to explain.


Although the vast majority of our explanations score poorly, we believe we can now use ML techniques to further improve our ability to produce explanations. For example, we found we were able to improve scores by:

  • Iterating on explanations. We can increase scores by asking GPT-4 to come up with possible counterexamples, then revising explanations in light of their activations.

  • Using larger models to give explanations. The average score goes up as the explainer model’s capabilities increase. However, even GPT-4 gives worse explanations than humans, suggesting room for improvement.

  • Changing the architecture of the explained model. Training models with different activation functions improved explanation scores.

We are open-sourcing our datasets and visualization tools for GPT-4-written explanations of all 307,200 neurons in GPT-2, as well as code for explanation and scoring using publicly available models(opens in a new window) on the OpenAI API. We hope the research community will develop new techniques for generating higher-scoring explanations and better tools for exploring GPT-2 using explanations.

We found over 1,000 neurons with explanations that scored at least 0.8, meaning that according to GPT-4 they account for most of the neuron’s top-activating behavior. Most of these well-explained neurons are not very interesting. However, we also found many interesting neurons that GPT-4 didn't understand. We hope as explanations improve we may be able to rapidly uncover interesting qualitative understanding of model computations.



Our method currently has many limitations(opens in a new window), which we hope can be addressed in future work.

  • We focused on short natural language explanations, but neurons may have very complex behavior that is impossible to describe succinctly. For example, neurons could be highly polysemantic (representing many distinct concepts) or could represent single concepts that humans don't understand or have words for.

  • We want to eventually automatically find and explain entire neural circuits(opens in a new window) implementing complex behaviors, with neurons and attention heads working together. Our current method only explains neuron behavior as a function of the original text input, without saying anything about its downstream effects. For example, a neuron that activates on periods could be indicating the next word should start with a capital letter, or be incrementing a sentence counter.

  • We explained the behavior of neurons without attempting to explain the mechanisms that produce that behavior. This means that even high-scoring explanations could do very poorly on out-of-distribution texts, since they are simply describing a correlation.

  • Our overall procedure is quite compute intensive.

We are excited about extensions and generalizations of our approach. Ultimately, we would like to use models to form, test, and iterate on fully general hypotheses just as an interpretability researcher would.

Eventually we want to interpret our largest models as a way to detect alignment and safety problems before and after deployment. However, we still have a long way to go before these techniques can surface behaviors like dishonesty.


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