Breaking Symmetries of the Reservoir Equations in Echo State Networks
Joschka Herteux, Christoph R\"ath
TL;DR
This paper analyzes the symmetry issues in reservoir computing, especially in echo state networks, and compares four methods to break this symmetry to improve nonlinear time-series prediction.
Contribution
It provides an analytical proof of symmetry caused by the hyperbolic tangent activation and evaluates four symmetry-breaking techniques through numerical experiments.
Findings
Input shift and quadratic readout effectively break symmetry.
Symmetry-breaking methods improve short-term prediction accuracy.
All methods except output bias successfully eliminate mirror-attractor.
Abstract
Reservoir computing has repeatedly been shown to be extremely successful in the prediction of nonlinear time-series. However, there is no complete understanding of the proper design of a reservoir yet. We find that the simplest popular setup has a harmful symmetry, which leads to the prediction of what we call mirror-attractor. We prove this analytically. Similar problems can arise in a general context, and we use them to explain the success or failure of some designs. The symmetry is a direct consequence of the hyperbolic tangent activation function. Further, four ways to break the symmetry are compared numerically: A bias in the output, a shift in the input, a quadratic term in the readout, and a mixture of even and odd activation functions. Firstly, we test their susceptibility to the mirror-attractor. Secondly, we evaluate their performance on the task of predicting Lorenz data with…
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