English

LLM Evaluation as Tensor Completion: Low Rank Structure and Semiparametric Efficiency

Methodology 2026-04-08 v1 Artificial Intelligence

Abstract

Large language model (LLM) evaluation platforms increasingly rely on pairwise human judgments. These data are noisy, sparse, and non-uniform, yet leaderboards are reported with limited uncertainty quantification. We study this as semiparametric inference for a low-rank latent score tensor observed through pairwise comparisons under Bradley-Terry-Luce-type models. This places LLM evaluation in a new tensor completion setting with structured observations, non-uniform sampling, and pairwise contrasts. Our target is a smooth functional ψ(T)\psi(T^\star), including linear estimands such as ability gaps and nonlinear ones such as win probabilities. We derive the information operator on the low-rank tangent space, the efficient influence function, and the semiparametric efficiency bound, then construct a one-step debiased estimator with asymptotic normality. A central challenge is that the information operator is anisotropic and does not commute with the tangent-space projection, creating a bottleneck absent from isotropic models. We introduce a score-whitening method that equalizes local Fisher information and restores stable inference at the optimal sample-complexity scale. Our results provide a principled framework for uncertainty quantification in LLM evaluation and more broadly for inference on low-rank structures from pairwise data.

Keywords

Cite

@article{arxiv.2604.05460,
  title  = {LLM Evaluation as Tensor Completion: Low Rank Structure and Semiparametric Efficiency},
  author = {Jiachun Li and David Simchi-Levi and Will Wei Sun},
  journal= {arXiv preprint arXiv:2604.05460},
  year   = {2026}
}
R2 v1 2026-07-01T11:56:41.707Z