English

JacQuant: STE-Free Quantization-Aware Training via Learned Jacobian Surrogates

Machine Learning 2026-05-26 v1

Abstract

Quantization-aware training (QAT) is widely deployed but typically relies on the Straight-Through Estimator (STE), which passes gradients through non-differentiable quantizers by fiat. This often makes training brittle near bin boundaries and weakly aligned with the actual behavior of the low-precision model. We introduce JacQuant, a QAT framework that learns a lightweight surrogate of the model's local sensitivity to parameter changes and uses it to stabilize and accelerate training within standard variance-reduced optimizers. The surrogate is inexpensive (diagonal or block-diagonal), data-driven, and compatible with common weight and activation quantizers. On code-preserving training phases, we prove convergence for non-convex objectives and obtain linear rates under a PL condition, and we relate the learned sensitivity to end-to-end output fidelity via a simple calibration argument. Across LLM benchmarks at 2\leq 2 bits, JacQuant consistently reaches higher accuracy than STE-based QAT, and the runtime analyses on various models show that the added cost remains negligible under practical group sizes. The method is drop-in and requires no changes to the forward quantizers; our empirical claims are scoped to ultra-low-bit LLM QAT.

Cite

@article{arxiv.2605.25469,
  title  = {JacQuant: STE-Free Quantization-Aware Training via Learned Jacobian Surrogates},
  author = {Kai Yi and Vignesh Vivekraja and Harshit Khaitan and Steven Li},
  journal= {arXiv preprint arXiv:2605.25469},
  year   = {2026}
}