A method is provided for designing and training noise-driven recurrent neural
networks as models of stochastic processes. The method unifies and generalizes
two known separate modeling approaches, Echo State Networks (ESN) and Linear
Inverse Modeling (LIM), under the common principle of relative entropy
minimization. The power of the new method is demonstrated on a stochastic
approximation of the El Nino phenomenon studied in climate research

Galtier, Mathieu N.

Jaeger, Herbert

Marini, Camille

Wainrib, Gilles

English

arXiv

International audienceA method is provided for designing and training noise-driven recurrent neural networks as models of stochastic processes. The method unifies and generalizes two known separate modeling approaches, Echo State Networks (ESN) and Linear Inverse Modeling (LIM), under the common principle of relative entropy minimization. The power of the new method is demonstrated on a stochastic approximation of the El Niño phenomenon studied in climate research

Galtier, Mathieu N

Jaeger, H.

HAL-MINES ParisTech

Relative entropy minimizing noisy non-linear neural network to approximate stochastic processes

HAL-Paris 13

http://www.sciencedirect.com/science/article/pii/S0893608014000860.

Relative entropy minimizing noisy non-linear neural network to
  approximate stochastic processes

Relative entropy minimizing noisy non-linear neural network to approximate stochastic processes

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HAL-MINES ParisTech

HAL-Paris 13