Dynamic Caustics by Ultrasonically Modulated Liquid Surface

TL;DR

This paper introduces a novel method for creating dynamic caustic patterns on liquid surfaces using ultrasonic manipulation and a Digital Twin framework, enabling real-time, controllable, and complex visual effects.

Contribution

It extends caustic generation techniques by integrating liquid surfaces with ultrasonic control and real-time feedback, advancing practical applications of dynamic caustics.

Findings

Successful generation of high-frequency dynamic caustic patterns

Demonstrated real-time control and animation of caustics

Identified limitations in contrast and resolution

Abstract

This paper presents a method for generating dynamic caustic patterns by utilising dual-optimised holographic fields with Phased Array Transducer (PAT). Building on previous research in static caustic optimisation and ultrasonic manipulation, this approach employs computational techniques to dynamically shape fluid surfaces, thereby creating controllable and real-time caustic images. The system employs a Digital Twin framework, which enables iterative feedback and refinement, thereby improving the accuracy and quality of the caustic patterns produced. This paper extends the foundational work in caustic generation by integrating liquid surfaces as refractive media. This concept has previously been explored in simulations but not fully realised in practical applications. The utilisation of ultrasound to directly manipulate these surfaces enables the generation of dynamic caustics with a high degree of flexibility. The Digital Twin approach further enhances this process by allowing for precise adjustments and optimisation based on real-time feedback. Experimental results demonstrate the technique's capacity to generate continuous animations and complex caustic patterns at high frequencies. Although there are limitations in contrast and resolution compared to solid-surface methods, this approach offers advantages in terms of real-time adaptability and scalability. This technique has the potential to be applied in a number of areas, including interactive displays, artistic installations and educational tools. This research builds upon the work of previous researchers in the fields of caustics optimisation, ultrasonic manipulation, and computational displays. Future research will concentrate on enhancing the resolution and intricacy of the generated patterns.