Energy cost for target control of complex networks

TL;DR

This paper derives the minimum energy cost for controlling specific subnetworks within complex networks, revealing how partial controllability can significantly reduce energy expenditure and providing bounds and scaling laws for practical target control.

Contribution

It introduces a systematic framework for calculating the minimum energy cost for target control in complex networks, including bounds, scaling behavior, and the impact of partial controllability.

Findings

Energy cost can vary by orders of magnitude across configurations.

Partial controllability significantly reduces energy expenditure.

Bounds and scaling laws for energy cost are established.

Abstract

To promote the implementation of realistic control over various complex networks, recent work has been focusing on analyzing energy cost. Indeed, the energy cost quantifies how much effort is required to drive the system from one state to another when it is fully controllable. A fully controllable system means that the system can be driven by external inputs from any initial state to any final state in finite time. However, it is prohibitively expensive and unnecessary to confine that the system is fully controllable when we merely need to accomplish the so-called target control---controlling a subnet of nodes chosen from the entire network. Yet, when the system is partially controllable, the associated energy cost remains elusive. Here we present the minimum energy cost for controlling an arbitrary subset of nodes of a network. Moreover, we systematically show the scaling behavior of the precise upper and lower bounds of the minimum energy in term of the time given to accomplish control. For controlling a given number of target nodes, we further demonstrate that the associated energy over different configurations can differ by several orders of magnitude. When the adjacency matrix of the network is nonsingular, we can simplify the framework by just considering the induced subgraph spanned by target nodes instead of the entire network. Importantly, we find that, energy cost could be saved by orders of magnitude as we only need the partial controllability of the entire network. Our theoretical results are all corroborated by numerical calculations, and pave the way for estimating the energy cost to implement realistic target control in various applications.