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Learning Shrinks the Hard Tail: Training-Dependent Inference Scaling in a Solvable Linear Model

Machine Learning 2026-01-08 v1 Disordered Systems and Neural Networks Artificial Intelligence Machine Learning

Abstract

We analyze neural scaling laws in a solvable model of last-layer fine-tuning where targets have intrinsic, instance-heterogeneous difficulty. In our Latent Instance Difficulty (LID) model, each input's target variance is governed by a latent ``precision'' drawn from a heavy-tailed distribution. While generalization loss recovers standard scaling laws, our main contribution connects this to inference. The pass@kk failure rate exhibits a power-law decay, kβeffk^{-\beta_\text{eff}}, but the observed exponent βeff\beta_\text{eff} is training-dependent. It grows with sample size NN before saturating at an intrinsic limit β\beta set by the difficulty distribution's tail. This coupling reveals that learning shrinks the ``hard tail'' of the error distribution: improvements in the model's generalization error steepen the pass@kk curve until irreducible target variance dominates. The LID model yields testable, closed-form predictions for this behavior, including a compute-allocation rule that favors training before saturation and inference attempts after. We validate these predictions in simulations and in two real-data proxies: CIFAR-10H (human-label variance) and a maths teacher-student distillation task.

Keywords

Cite

@article{arxiv.2601.03764,
  title  = {Learning Shrinks the Hard Tail: Training-Dependent Inference Scaling in a Solvable Linear Model},
  author = {Noam Levi},
  journal= {arXiv preprint arXiv:2601.03764},
  year   = {2026}
}

Comments

10 pages

R2 v1 2026-07-01T08:54:03.379Z