Latent Trajectory Dynamics in Large Language Models: A Manifold Evolution Framework with Empirical Validation

Abstract

Understanding how latent representations evolve during generation is a central open problem in large language model interpretability. We introduce Dynamical Manifold Evolution Theory (DMET), a phenomenological framework that models LLM generation as a controlled dynamical system evolving along a trajectory on a low-dimensional semantic manifold. DMET formalizes the structural correspondence between Transformer components and a first-order ODE governed by a semantic potential V, and characterizes trajectory geometry through three falsifiable proxy metrics: state continuity C, attractor clustering quality Q, and topological persistence P, targeting local smoothness, meso-scale basin structure, and global topological organization, respectively. Across six model architectures, four task types, and 1,080 experimental runs, all three metrics consistently predict text quality outcomes -- log-perplexity, grammaticality, and cross-sentence coherence -- after controlling for decoding parameters, with associations surviving Benjamini--Hochberg correction. Ablation and sanity-check experiments confirm that the effects arise from genuine trajectory structure rather than static distributional artefacts. Furthermore, online monitoring of C drives an adaptive decoding controller that reduces perplexity from 48.5 to 14.6 relative to a fixed-parameter baseline, demonstrating that latent dynamics characterization translates directly into actionable generation control.