Passivity-preserving splitting methods for rigid body systems
For researchers simulating offshore pipe-lay operations, this work provides a numerical method that maintains the passivity property of the system, which is crucial for stability in coupled simulations.
The paper proposes passivity-preserving splitting methods for rigid body systems, such as marine vessel dynamics, and proves their passivity-preservation property with stability and energy behavior validated in numerical experiments.
A rigid body model for the dynamics of a marine vessel, used in simulations of offshore pipe-lay operations, gives rise to a set of ordinary differential equations with controls. The system is input-output passive. We propose passivity-preserving splitting methods for the numerical solution of a class of problems which includes this system as a special case. We prove the passivity-preservation property for the splitting methods, and we investigate stability and energy behaviour in numerical experiments. Implementation is discussed in detail for a special case where the splitting gives rise to the subsequent integration of two completely integrable flows. The equations for the attitude are reformulated on $SO(3)$ using rotation matrices rather than local parametrizations with Euler angles.