Modelling and closed loop control of near-field acoustically levitated objects

TL;DR

This paper presents a simplified second-order model for near-field acoustic levitation, enabling effective closed-loop control of object height, and demonstrates its practical application through a gain-scheduled PID controller validated experimentally.

Contribution

It introduces a concise, explicit second-order model for levitated object dynamics, facilitating the design of effective control algorithms for acoustic levitation systems.

Findings

The simplified model accurately predicts the slow dynamics of levitated objects.

The gain-scheduled PID controller achieves precise vertical positioning.

Experimental results confirm the model's effectiveness in real-world scenarios.

Abstract

The present paper introduces a novel approach for modelling the governing, slow dynamics of near-field acoustically levitated objects. This model is sufficiently simple and concise to enable designing a closed-loop controller, capable of accurate vertical positioning of a carried object. The near-field acoustic levitation phenomenon exploits the compressibility, the nonlinearity and the viscosity of the gas trapped between a rapidly oscillating surface and a freely suspended planar object, to elevate its time averaged pressure above the ambient pressure. By these means, the vertical position of loads weighing up to several kilograms can be varied between dozens and hundreds of micrometers. The simplified model developed in this paper is a second order ordinary differential equation where the height-dependent stiffness and damping terms of the gas layer are derived explicitly. This simplified model replaces a traditional model consisting of the equation of motion of the levitated object, coupled to a nonlinear partial differential equation, accounting for the behavior of the entrapped gas. Due to the relatively simple form of the model developed here, it constitutes a convenient foundation for model based control algorithms, governing the slow dynamics of near-field acoustically levitated objects. Indeed, based on the former, a height dependent, gain scheduled PID controller is developed and verified numerically and experimentally, both providing satisfying results.