English

Transformers as Measure-Theoretic Associative Memory: A Statistical Perspective and Minimax Optimality

Machine Learning 2026-02-03 v1 Machine Learning

Abstract

Transformers excel through content-addressable retrieval and the ability to exploit contexts of, in principle, unbounded length. We recast associative memory at the level of probability measures, treating a context as a distribution over tokens and viewing attention as an integral operator on measures. Concretely, for mixture contexts ν=I1i=1Iμ(i)\nu = I^{-1} \sum_{i=1}^I \mu^{(i^*)} and a query xq(i)x_{\mathrm{q}}(i^*), the task decomposes into (i) recall of the relevant component μ(i)\mu^{(i^*)} and (ii) prediction from (μi,xq)(\mu_{i^*},x_\mathrm{q}). We study learned softmax attention (not a frozen kernel) trained by empirical risk minimization and show that a shallow measure-theoretic Transformer composed with an MLP learns the recall-and-predict map under a spectral assumption on the input densities. We further establish a matching minimax lower bound with the same rate exponent (up to multiplicative constants), proving sharpness of the convergence order. The framework offers a principled recipe for designing and analyzing Transformers that recall from arbitrarily long, distributional contexts with provable generalization guarantees.

Keywords

Cite

@article{arxiv.2602.01863,
  title  = {Transformers as Measure-Theoretic Associative Memory: A Statistical Perspective and Minimax Optimality},
  author = {Ryotaro Kawata and Taiji Suzuki},
  journal= {arXiv preprint arXiv:2602.01863},
  year   = {2026}
}
R2 v1 2026-07-01T09:31:24.834Z