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arxiv: 2509.04422 · v1 · pith:V5SN7Z36new · submitted 2025-09-04 · 💻 cs.LG

Echo State Networks as State-Space Models: A Systems Perspective

classification 💻 cs.LG
keywords stateesnsmodelsspectralssmsechofirstleak
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Echo State Networks (ESNs) are typically presented as efficient, readout-trained recurrent models, yet their dynamics and design are often guided by heuristics rather than first principles. We recast ESNs explicitly as state-space models (SSMs), providing a unified systems-theoretic account that links reservoir computing with classical identification and modern kernelized SSMs. First, we show that the echo-state property is an instance of input-to-state stability for a contractive nonlinear SSM and derive verifiable conditions in terms of leak, spectral scaling, and activation Lipschitz constants. Second, we develop two complementary mappings: (i) small-signal linearizations that yield locally valid LTI SSMs with interpretable poles and memory horizons; and (ii) lifted/Koopman random-feature expansions that render the ESN a linear SSM in an augmented state, enabling transfer-function and convolutional-kernel analyses. This perspective yields frequency-domain characterizations of memory spectra and clarifies when ESNs emulate structured SSM kernels. Third, we cast teacher forcing as state estimation and propose Kalman/EKF-assisted readout learning, together with EM for hyperparameters (leak, spectral radius, process/measurement noise) and a hybrid subspace procedure for spectral shaping under contraction constraints.

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Reviewed papers in the Pith corpus that reference this work. Sorted by Pith novelty score.

  1. Frequency Domain Reservoir Computing

    cs.LG 2026-06 unverdicted novelty 7.0

    FRESCO is a frequency-domain Echo State Network using zero-padding embeddings, packed readout, and native frequency non-linearity to achieve O(N) complexity while matching SOTA on memory and forecasting benchmarks.