Local homeostatic regulation of the spectral radius of echo-state networks

TL;DR

This paper introduces biologically plausible local homeostatic mechanisms, flow control and variance control, that regulate the spectral radius of echo-state networks, enabling autonomous adaptation for optimal sequential processing.

Contribution

It presents two novel local adaptation mechanisms for spectral radius regulation in recurrent networks, avoiding the need for global parameter tuning.

Findings

Flow control reliably regulates spectral radius across input types.

Task performance remains stable over various input strengths.

Variance control is less consistent in achieving desired spectral radii.

Abstract

Recurrent cortical networks provide reservoirs of states that are thought to play a crucial role for sequential information processing in the brain. However, classical reservoir computing requires manual adjustments of global network parameters, particularly of the spectral radius of the recurrent synaptic weight matrix. It is hence not clear if the spectral radius is accessible to biological neural networks. Using random matrix theory, we show that the spectral radius is related to local properties of the neuronal dynamics whenever the overall dynamical state is only weakly correlated. This result allows us to introduce two local homeostatic synaptic scaling mechanisms, termed flow control and variance control, that implicitly drive the spectral radius towards the desired value under working conditions. We demonstrate the effectiveness of the two adaptation mechanisms under different external input protocols and the network performance after adaptation by training the network to perform a time-delayed XOR operation on binary sequences. As our main result, we found that flow control reliably regulates the spectral radius for different types of input statistics. Precise tuning is however negatively affected when interneural correlations are substantial. Furthermore, we found a consistent task performance over a wide range of input strengths/variances. Variance control did however not yield the desired spectral radii with the same precision, being less consistent across different input strengths. Given the effectiveness and remarkably simple mathematical form of flow control, we conclude that self-consistent local control of the spectral radius via an implicit adaptation scheme is an interesting and biological plausible alternative to conventional methods using setpoint homeostatic feedback controls of neural firing.