In this work, we give a characterization of the reservoir computer (RC) by the network structure, especially the probability distribution of random coupling constants. First, based on the path integral method, we clarify the universal behavior of the random network dynamics in the thermodynamic limit, which depends only on the asymptotic behavior of the second cumulant generating functions of the network coupling constants. This result enables us to classify the random networks into several universality classes, according to the distribution function of coupling constants chosen for the networks. Interestingly, it is revealed that such a classification has a close relationship with the distribution of eigenvalues of the random coupling matr...
Analysis and prediction of real-world complex systems of nonlinear dynamics relies largely on surrog...
Reservoir computing (RC) is a brain-inspired computing framework that employs a transient dynamical ...
© 2015 Massachusetts Institute of Technology. Supplementing a differential equation with delays resu...
A new explanation of the geometric nature of the reservoir computing (RC) phenomenon is presented. R...
The interplay between randomness and optimization has always been a major theme in the design of neu...
The remarkable properties of information-processing by biological and artificial neuronal networks a...
Reservoir Computing (RC) offers a computationally efficient and well performing technique for using the...
Reservoir computing (RC) studies the properties of large recurrent networks of artificial neurons, w...
Reservoir computing (RC) is a promising paradigm for time series processing. In this paradigm, the d...
Reservoir computing (RC), a relatively new approach to machine learning, utilizes untrained recurren...
The human brain's synapses have remarkable activity-dependent plasticity, where the connectivity pat...
Reservoir computing (RC), first applied to temporal signal processing, is a recurrent neural network...
Reservoir computing (RC) systems are powerful models for online computations on input sequences. The...
Dynamical systems suited for Reservoir Computing (RC) should be able to both retain information for ...
It has been demonstrated that in the realm of complex systems not only exact predic-tions of multiva...
Analysis and prediction of real-world complex systems of nonlinear dynamics relies largely on surrog...
Reservoir computing (RC) is a brain-inspired computing framework that employs a transient dynamical ...
© 2015 Massachusetts Institute of Technology. Supplementing a differential equation with delays resu...
A new explanation of the geometric nature of the reservoir computing (RC) phenomenon is presented. R...
The interplay between randomness and optimization has always been a major theme in the design of neu...
The remarkable properties of information-processing by biological and artificial neuronal networks a...
Reservoir Computing (RC) offers a computationally efficient and well performing technique for using the...
Reservoir computing (RC) studies the properties of large recurrent networks of artificial neurons, w...
Reservoir computing (RC) is a promising paradigm for time series processing. In this paradigm, the d...
Reservoir computing (RC), a relatively new approach to machine learning, utilizes untrained recurren...
The human brain's synapses have remarkable activity-dependent plasticity, where the connectivity pat...
Reservoir computing (RC), first applied to temporal signal processing, is a recurrent neural network...
Reservoir computing (RC) systems are powerful models for online computations on input sequences. The...
Dynamical systems suited for Reservoir Computing (RC) should be able to both retain information for ...
It has been demonstrated that in the realm of complex systems not only exact predic-tions of multiva...
Analysis and prediction of real-world complex systems of nonlinear dynamics relies largely on surrog...
Reservoir computing (RC) is a brain-inspired computing framework that employs a transient dynamical ...
© 2015 Massachusetts Institute of Technology. Supplementing a differential equation with delays resu...