Collision-avoiding in the singular Cucker-Smale model with nonlinear velocity couplings

TL;DR

This paper extends collision avoidance results in the singular Cucker-Smale model to cases with nonlinear velocity couplings, proving no finite-time collisions occur under certain conditions and providing uniform estimates for inter-particle distances.

Contribution

It generalizes previous collision avoidance proofs to nonlinear velocity couplings in the singular Cucker-Smale model, including expanded singularity weights.

Findings

Particles avoid collisions even with nonlinear velocity couplings.

No finite-time collisions occur for   1.

Uniform estimates for inter-particle distances with expanded singularity weights.

Abstract

Collision avoidance is an interesting feature of the Cucker-Smale (CS) model of flocking that has been studied in many works, e.g. [1, 2, 4, 6, 7, 20, 21, 22]. In particular, in the case of singular interactions between agents, as is the case of the CS model with communication weights of the type $\psi(s)=s^{-\alpha}$ for $\alpha \geq 1$, it is important for showing global well-posedness of the underlying particle dynamics. In [4], a proof of the non-collision property for singular interactions is given in the case of the linear CS model, i.e. when the velocity coupling between agents $i,j$ is $v_{j}-v_{i}$. This paper can be seen as an extension of the analysis in [4]. We show that particles avoid collisions even when the linear coupling in the CS system has been substituted with the nonlinear term $\Gamma(\cdot)$ introduced in [12] (typical examples being $\Gamma(v)=v|v|^{2(\gamma -1)}$ for $\gamma \in (\frac{1}{2},\frac{3}{2})$), and prove that no collisions can happen in finite time when $\alpha \geq 1$. We also show uniform estimates for the minimum inter-particle distance, for a communication weight with expanded singularity $\psi_{\delta}(s)=(s-\delta)^{-\alpha}$, when $\alpha \geq 2\gamma$, $\delta \geq 0$.