Reservoir states are designed to concentrate increments in input-determined subspaces via cone alignment, reducing ridge-regression error for deterministic dynamical system inputs.
Stochastic dynamics learning with state-space systems
3 Pith papers cite this work. Polarity classification is still indexing.
abstract
This work advances the theoretical foundations of reservoir computing (RC) by providing a unified treatment of fading memory and the echo state property (ESP) in both deterministic and stochastic settings. We investigate state-space systems, a central model class in time series learning, and establish that fading memory and solution stability hold generically -- even in the absence of the ESP -- offering a robust explanation for the empirical success of RC models without strict contractivity conditions. In the stochastic case, we critically assess stochastic echo states, proposing a novel distributional perspective rooted in attractor dynamics on the space of probability distributions, which leads to a rich and coherent theory. Our results extend and generalize previous work on non-autonomous dynamical systems, offering new insights into causality, stability, and memory in RC models. This lays the groundwork for reliable generative modeling of temporal data in both deterministic and stochastic regimes.
verdicts
UNVERDICTED 3representative citing papers
The paper unifies fading memory, echo states, and related memory notions in RNNs via new equivalences, implications, and alternative proofs.
A C1-close state-space proxy can keep forecasted distributions close to the true long-term distribution for structurally stable mixing dynamical systems.
citing papers explorer
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Data-Specific Hyper-Parameter Design: A Paradigm Shift in Reservoir Computing
Reservoir states are designed to concentrate increments in input-determined subspaces via cone alignment, reducing ridge-regression error for deterministic dynamical system inputs.