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Research PaperResearchia:202607.07007

What Does a Discrete Diffusion Model Learn?

Rodrigo Casado Noguerales

Abstract

What does a discrete diffusion model learn: a denoiser, a score ratio, or a bridge plug-in predictor? At the level of jump rates, these are one object in different coordinates, and reading a neural network in the wrong coordinate changes the process being trained and sampled. Starting with a rigorous derivation of the continuous-time Markov chain (CTMC) ELBO for any noising process, boundary terms included, we prove the \emph{Oracle Distance} theorem: the negative ELBO is exactly equal to the da...

Submitted: July 7, 2026Subjects: NLP; Computational Linguistics

Description / Details

What does a discrete diffusion model learn: a denoiser, a score ratio, or a bridge plug-in predictor? At the level of jump rates, these are one object in different coordinates, and reading a neural network in the wrong coordinate changes the process being trained and sampled. Starting with a rigorous derivation of the continuous-time Markov chain (CTMC) ELBO for any noising process, boundary terms included, we prove the \emph{Oracle Distance} theorem: the negative ELBO is exactly equal to the data entropy plus the path KL from the oracle reverse process to the learned one, not merely a bound. Its unique optimizer is therefore the conditional expectation of the true reverse jump rate given the current noisy state, and its irreducible cost is the rate at which the forward process ZtZ_t destroys information about the clean data Z0Z_0, βˆ’ddtI(Z0;Zt)-\tfrac{d}{dt}I(Z_0; Z_t), so every noising process shares the same best achievable negative ELBO: the data entropy. For sequences with token-factorizing noise, the oracle projection yields three exact coordinates for the optimizer: denoiser, cavity (bridge plug-in), and score, with closed-form conversions among them. This framework identifies which law each loss in the literature actually optimizes, recovering MDM, UDM, SEDD, and GIDD as special cases; explains why denoiser and cavity coincide for masked diffusion but not for uniform diffusion; proves that a denoiser parameterization makes the uniform ELBO diverge at initialization while the bridge plug-in stays finite; and calibrates ELBO implementations exactly at initialization. Every identity is verified numerically, without approximation, on an exactly solvable model.


Source: arXiv:2607.05381v1 - http://arxiv.org/abs/2607.05381v1 PDF: https://arxiv.org/pdf/2607.05381v1 Original Link: http://arxiv.org/abs/2607.05381v1

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Submission Info
Date:
Jul 7, 2026
Topic:
Computational Linguistics
Area:
NLP
Comments:
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