In-Context Learning of Energy Functions
This work addresses a fundamental constraint in in-context learning for AI models, offering a novel approach that could broaden its applicability, though it is incremental as it builds on energy-based modeling.
The paper tackles the limitation of in-context learning to settings with straightforwardly parameterized distributions by proposing a more general form that learns arbitrary energy functions, providing preliminary evidence on synthetic data.
In-context learning is a powerful capability of certain machine learning models that arguably underpins the success of today's frontier AI models. However, in-context learning is critically limited to settings where the in-context distribution of interest $p_θ^{ICL}( x|\mathcal{D})$ can be straightforwardly expressed and/or parameterized by the model; for instance, language modeling relies on expressing the next-token distribution as a categorical distribution parameterized by the network's output logits. In this work, we present a more general form of in-context learning without such a limitation that we call \textit{in-context learning of energy functions}. The idea is to instead learn the unconstrained and arbitrary in-context energy function $E_θ^{ICL}(x|\mathcal{D})$ corresponding to the in-context distribution $p_θ^{ICL}(x|\mathcal{D})$. To do this, we use classic ideas from energy-based modeling. We provide preliminary evidence that our method empirically works on synthetic data. Interestingly, our work contributes (to the best of our knowledge) the first example of in-context learning where the input space and output space differ from one another, suggesting that in-context learning is a more-general capability than previously realized.