We show that double mills are more stable than single mills under stochastic perturbations in swarming dynamic models with basic attraction-repulsion mechanisms. In order to analyse this fact accurately, we will present a numerical technique for solving kinetic mean field equations for swarming dynamics. Numerical solutions of these equations for different sets of parameters will be presented and compared to microscopic and macroscopic results. As a consequence, we numerically observe a phase transition diagram in terms of the stochastic noise going from single to double mill for small stochasticity fading gradually to disordered states when the noise strength gets larger. This bifurcation diagram at the inhomogeneous kinetic level is shown by carefully computing the distribution function in velocity space

Carrillo, JA

Klar, A

Roth, A

Communications in Mathematical Sciences

We show that double mills are more stable than single mills under stochastic perturbations in swarming dynamic models with basic attraction–repulsion mechanisms. In order to analyse this fact accurately, we will present a numerical technique for solving kinetic mean field equations for swarming dynamics. Numerical solutions of these equations for different sets of parameters will be presented and compared to microscopic and macroscopic results. As a consequence, we numerically observe a phase transition diagram in terms of the stochastic noise going from single to double mill for small stochasticity fading gradually to disordered states when the noise strength gets larger. This bifurcation diagram at the inhomogeneous kinetic level is shown by carefully computing the distribution function in velocity space

Carrillo de la Plata, Jose

Klar, Axel

Roth, Andreas

Oxford University Research Archive

Single to double mill small noise transition via semi-Lagrangian finite volume methods

ORA - Oxford University Research Archive

Abstract. We show that double mills are more stable than single mills under stochastic pertur-bations in swarming dynamic models with basic attraction-repulsion mechanisms. In order to analyse accurately this fact, we will present a numerical technique for solving kinetic mean field equations for swarming dynamics. Numerical solutions of these equations for different sets of parameters will be presented and compared to microscopic and macroscopic results. As a consequence, we numeri-cally observe a phase transition diagram in term of the stochastic noise going from single to double mill for small stochasticity fading gradually to disordered states when the noise strength gets larger. This bifurcation diagram at the inhomogeneous kinetic level is shown by carefully computing the distribution function in velocity space

J. A. Carrillo

A. Klar

A. Roth

CiteSeerX

SINGLE TO DOUBLE MILL SMALL NOISE TRANSITION VIA SEMI-LAGRANGIAN FINITE VOLUME METHODS

Spiral - Imperial College Digital Repository

Carrillo, J.A.

Klar, A.

Roth, A.

Fraunhofer-ePrints

Single to double mill small noise transition via semi-lagrangian finite volume methods

Single to double mill small noise transition via semi-Lagrangian finite volume methods

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Oxford University Research Archive

ORA - Oxford University Research Archive

CiteSeerX

Spiral - Imperial College Digital Repository

Fraunhofer-ePrints