English

NeuralFluid: Neural Fluidic System Design and Control with Differentiable Simulation

Fluid Dynamics 2024-11-04 v2 Artificial Intelligence Graphics

Abstract

We present a novel framework to explore neural control and design of complex fluidic systems with dynamic solid boundaries. Our system features a fast differentiable Navier-Stokes solver with solid-fluid interface handling, a low-dimensional differentiable parametric geometry representation, a control-shape co-design algorithm, and gym-like simulation environments to facilitate various fluidic control design applications. Additionally, we present a benchmark of design, control, and learning tasks on high-fidelity, high-resolution dynamic fluid environments that pose challenges for existing differentiable fluid simulators. These tasks include designing the control of artificial hearts, identifying robotic end-effector shapes, and controlling a fluid gate. By seamlessly incorporating our differentiable fluid simulator into a learning framework, we demonstrate successful design, control, and learning results that surpass gradient-free solutions in these benchmark tasks.

Keywords

Cite

@article{arxiv.2405.14903,
  title  = {NeuralFluid: Neural Fluidic System Design and Control with Differentiable Simulation},
  author = {Yifei Li and Yuchen Sun and Pingchuan Ma and Eftychios Sifakis and Tao Du and Bo Zhu and Wojciech Matusik},
  journal= {arXiv preprint arXiv:2405.14903},
  year   = {2024}
}

Comments

Accepted to NeurIPS 2024; Project webpage: https://people.csail.mit.edu/liyifei/publication/neuralfluid/

R2 v1 2026-06-28T16:37:50.224Z