The Effect of Signaling Latencies and Node Refractory States on the Dynamics of Networks

TL;DR

This paper introduces a neurophysiologically inspired framework modeling how signaling latencies and refractory states influence network dynamics, leading to a geometric perceptron model with bounds on efficient signaling based on timing constraints.

Contribution

It presents a novel theoretical framework connecting neurophysiological principles to network signaling, extending to a geometric perceptron and establishing bounds on signaling efficiency.

Findings

Derived bounds for optimal signaling based on timing constraints

Developed a geometric dynamic perceptron model

Identified how timing mismatches disrupt network signaling

Abstract

We describe the construction and theoretical analysis of a framework derived from canonical neurophysiological principles that model the competing dynamics of incident signals into nodes along directed edges in a network. The framework describes the dynamics between the offset in the latencies of propagating signals, which reflect the geometry of the edges and conduction velocities, and the internal refractory dynamics and processing times of the downstream node receiving the signals. This framework naturally extends to the construction of a perceptron model that takes into account such dynamic geometric considerations. We first describe the model in detail, culminating with the model of a geometric dynamic perceptron. We then derive upper and lower bounds for a notion of optimal efficient signaling between vertex pairs based on the structure of the framework. Efficient signaling in the context of the framework we develop here means that there needs to be a temporal match between the arrival time of the signals relative to how quickly nodes can internally process signals. These bounds reflect numerical constraints on the compensation of the timing of signaling events of upstream nodes attempting to activate downstream nodes they connect into that preserve this notion of efficiency. When a mismatch between signal arrival times and the internal states of activated nodes occurs, it can cause a break down in the signaling dynamics of the network. In contrast to essentially all the current state of the art in machine learning, this work provides a theoretical foundation for machine learning and intelligence architectures based on the timing of node activations and their abilities to respond, rather than necessary changes in synaptic weights. At the same time, this work is guiding the discovery of experimentally testable new structure-function principles in the biological brain.